Although the term nephroid was used to describe other curves, it was applied to the curve in this article by Richard A. Proctor in 1878.^[1][2]

A nephroid is

• an algebraic curve of degree 6.
• an epicycloid with two cusps
• a plane simple closed curve = a Jordan curve

Equations edit

Parametric edit

If the small circle has radius ${\displaystyle a}$ , the fixed circle has midpoint ${\displaystyle (0,0)}$  and radius ${\displaystyle 2a}$ , the rolling angle of the small circle is ${\displaystyle 2\varphi }$  and point ${\displaystyle (2a,0)}$  the starting point (see diagram) then one gets the parametric representation:

${\displaystyle x(\varphi )=3a\cos \varphi -a\cos 3\varphi =6a\cos \varphi -4a\cos ^{3}\varphi \ ,}$ 

${\displaystyle y(\varphi )=3a\sin \varphi -a\sin 3\varphi =4a\sin ^{3}\varphi \ ,\qquad 0\leq \varphi <2\pi }$ 

The complex map ${\displaystyle z\to z^{3}+3z}$  maps the unit circle to a nephroid^[3]

Proof of the parametric representation edit

The proof of the parametric representation is easily done by using complex numbers and their representation as complex plane. The movement of the small circle can be split into two rotations. In the complex plane a rotation of a point ${\displaystyle z}$  around point ${\displaystyle 0}$  (origin) by an angle ${\displaystyle \varphi }$  can be performed by the multiplication of point ${\displaystyle z}$  (complex number) by ${\displaystyle e^{i\varphi }}$ . Hence the

rotation ${\displaystyle \Phi _{3}}$  around point ${\displaystyle 3a}$  by angle ${\displaystyle 2\varphi }$  is ${\displaystyle :z\mapsto 3a+(z-3a)e^{i2\varphi }}$  ,

rotation ${\displaystyle \Phi _{0}}$  around point ${\displaystyle 0}$  by angle ${\displaystyle \varphi }$  is ${\displaystyle :\quad z\mapsto ze^{i\varphi }}$ .

A point ${\displaystyle p(\varphi )}$  of the nephroid is generated by the rotation of point ${\displaystyle 2a}$  by ${\displaystyle \Phi _{3}}$  and the subsequent rotation with ${\displaystyle \Phi _{0}}$ :

${\displaystyle p(\varphi )=\Phi _{0}(\Phi _{3}(2a))=\Phi _{0}(3a-ae^{i2\varphi })=(3a-ae^{i2\varphi })e^{i\varphi }=3ae^{i\varphi }-ae^{i3\varphi }}$ .

Herefrom one gets

${\displaystyle {\begin{array}{cclcccc}x(\varphi )&=&3a\cos \varphi -a\cos 3\varphi &=&6a\cos \varphi -4a\cos ^{3}\varphi \ ,&&\\y(\varphi )&=&3a\sin \varphi -a\sin 3\varphi &=&4a\sin ^{3}\varphi &.&\end{array}}}$ 

(The formulae ${\displaystyle e^{i\varphi }=\cos \varphi +i\sin \varphi ,\ \cos ^{2}\varphi +\sin ^{2}\varphi =1,\ \cos 3\varphi =4\cos ^{3}\varphi -3\cos \varphi ,\;\sin 3\varphi =3\sin \varphi -4\sin ^{3}\varphi }$  were used. See trigonometric functions.)

Implicit edit

Inserting ${\displaystyle x(\varphi )}$  and ${\displaystyle y(\varphi )}$  into the equation

• ${\displaystyle (x^{2}+y^{2}-4a^{2})^{3}=108a^{4}y^{2}}$ 

shows that this equation is an implicit representation of the curve.

Proof of the implicit representation edit

With

${\displaystyle x^{2}+y^{2}-4a^{2}=(3a\cos \varphi -a\cos 3\varphi )^{2}+(3a\sin \varphi -a\sin 3\varphi )^{2}-4a^{2}=\cdots =6a^{2}(1-\cos 2\varphi )=12a^{2}\sin ^{2}\varphi }$ 

one gets

${\displaystyle (x^{2}+y^{2}-4a^{2})^{3}=(12a^{2})^{3}\sin ^{6}\varphi =108a^{4}(4a\sin ^{3}\varphi )^{2}=108a^{4}y^{2}\ .}$ 

If the cusps are on the y-axis the parametric representation is

${\displaystyle x=3a\cos \varphi +a\cos 3\varphi ,\quad y=3a\sin \varphi +a\sin 3\varphi ).}$ 

and the implicit one:

${\displaystyle (x^{2}+y^{2}-4a^{2})^{3}=108a^{4}x^{2}.}$ 

For the nephroid above the

• arclength is ${\displaystyle L=24a,}$ 
• area ${\displaystyle A=12\pi a^{2}\ }$  and
• radius of curvature is ${\displaystyle \rho =|3a\sin \varphi |.}$ 

The proofs of these statements use suitable formulae on curves (arc length, area and radius of curvature) and the parametric representation above

${\displaystyle x(\varphi )=6a\cos \varphi -4a\cos ^{3}\varphi \ ,}$ 

${\displaystyle y(\varphi )=4a\sin ^{3}\varphi }$ 

and their derivatives

${\displaystyle {\dot {x}}=-6a\sin \varphi (1-2\cos ^{2}\varphi )\ ,\quad \ {\ddot {x}}=-6a\cos \varphi (5-6\cos ^{2}\varphi )\ ,}$ 

${\displaystyle {\dot {y}}=12a\sin ^{2}\varphi \cos \varphi \quad ,\quad \quad \quad \quad {\ddot {y}}=12a\sin \varphi (3\cos ^{2}\varphi -1)\ .}$ 

Proof for the arc length

${\displaystyle L=2\int _{0}^{\pi }{\sqrt {{\dot {x}}^{2}+{\dot {y}}^{2}}}\;d\varphi =\cdots =12a\int _{0}^{\pi }\sin \varphi \;d\varphi =24a}$  .

Proof for the area

${\displaystyle A=2\cdot {\tfrac {1}{2}}|\int _{0}^{\pi }[x{\dot {y}}-y{\dot {x}}]\;d\varphi |=\cdots =24a^{2}\int _{0}^{\pi }\sin ^{2}\varphi \;d\varphi =12\pi a^{2}}$  .

Proof for the radius of curvature

${\displaystyle \rho =\left|{\frac {\left({{\dot {x}}^{2}+{\dot {y}}^{2}}\right)^{\frac {3}{2}}}{{\dot {x}}{\ddot {y}}-{\dot {y}}{\ddot {x}}}}\right|=\cdots =|3a\sin \varphi |.}$ 

• It can be generated by rolling a circle with radius ${\displaystyle a}$  on the outside of a fixed circle with radius ${\displaystyle 2a}$ . Hence, a nephroid is an epicycloid.

Nephroid as envelope of a pencil of circles edit

• Let be ${\displaystyle c_{0}}$  a circle and ${\displaystyle D_{1},D_{2}}$  points of a diameter ${\displaystyle d_{12}}$ , then the envelope of the pencil of circles, which have midpoints on ${\displaystyle c_{0}}$  and are touching ${\displaystyle d_{12}}$  is a nephroid with cusps ${\displaystyle D_{1},D_{2}}$ .

Proof edit

Let ${\displaystyle c_{0}}$  be the circle ${\displaystyle (2a\cos \varphi ,2a\sin \varphi )}$  with midpoint ${\displaystyle (0,0)}$  and radius ${\displaystyle 2a}$ . The diameter may lie on the x-axis (see diagram). The pencil of circles has equations:

${\displaystyle f(x,y,\varphi )=(x-2a\cos \varphi )^{2}+(y-2a\sin \varphi )^{2}-(2a\sin \varphi )^{2}=0\ .}$ 

The envelope condition is

${\displaystyle f_{\varphi }(x,y,\varphi )=2a(x\sin \varphi -y\cos \varphi -2a\cos \varphi \sin \varphi )=0\ .}$ 

One can easily check that the point of the nephroid ${\displaystyle p(\varphi )=(6a\cos \varphi -4a\cos ^{3}\varphi \;,\;4a\sin ^{3}\varphi )}$  is a solution of the system ${\displaystyle f(x,y,\varphi )=0,\;f_{\varphi }(x,y,\varphi )=0}$  and hence a point of the envelope of the pencil of circles.

Nephroid as envelope of a pencil of lines edit

Similar to the generation of a cardioid as envelope of a pencil of lines the following procedure holds:

1. Draw a circle, divide its perimeter into equal spaced parts with ${\displaystyle 3N}$  points (see diagram) and number them consecutively.
2. Draw the chords: ${\displaystyle (1,3),(2,6),....,(n,3n),....,(N,3N),(N+1,3),(N+2,6),....,}$ . (i.e.: The second point is moved by threefold velocity.)
3. The envelope of these chords is a nephroid.

Proof edit

The following consideration uses trigonometric formulae for ${\displaystyle \cos \alpha +\cos \beta ,\ \sin \alpha +\sin \beta ,\ \cos(\alpha +\beta ),\ \cos 2\alpha }$ . In order to keep the calculations simple, the proof is given for the nephroid with cusps on the y-axis. Equation of the tangent: for the nephroid with parametric representation

${\displaystyle x=3\cos \varphi +\cos 3\varphi ,\;y=3\sin \varphi +\sin 3\varphi }$ :

Herefrom one determines the normal vector ${\displaystyle {\vec {n}}=({\dot {y}},-{\dot {x}})^{T}}$ , at first.
The equation of the tangent ${\displaystyle {\dot {y}}(\varphi )\cdot (x-x(\varphi ))-{\dot {x}}(\varphi )\cdot (y-y(\varphi ))=0}$  is:

${\displaystyle (\cos 2\varphi \cdot x\ +\ \sin 2\varphi \cdot y)\cos \varphi =4\cos ^{2}\varphi \ .}$ 

For ${\displaystyle \varphi ={\tfrac {\pi }{2}},{\tfrac {3\pi }{2}}}$  one gets the cusps of the nephroid, where there is no tangent. For ${\displaystyle \varphi \neq {\tfrac {\pi }{2}},{\tfrac {3\pi }{2}}}$  one can divide by ${\displaystyle \cos \varphi }$  to obtain

• ${\displaystyle \cos 2\varphi \cdot x+\sin 2\varphi \cdot y=4\cos \varphi \ .}$ 

Equation of the chord: to the circle with midpoint ${\displaystyle (0,0)}$  and radius ${\displaystyle 4}$ : The equation of the chord containing the two points ${\displaystyle (4\cos \theta ,4\sin \theta ),\ (4\cos {\color {red}3}\theta ,4\sin {\color {red}3}\theta ))}$  is:

${\displaystyle (\cos 2\theta \cdot x+\sin 2\theta \cdot y)\sin \theta =4\cos \theta \sin \theta \ .}$ 

For ${\displaystyle \theta =0,\pi }$  the chord degenerates to a point. For ${\displaystyle \theta \neq 0,\pi }$  one can divide by ${\displaystyle \sin \theta }$  and gets the equation of the chord:

• ${\displaystyle \cos 2\theta \cdot x+\sin 2\theta \cdot y=4\cos \theta \ .}$ 

The two angles ${\displaystyle \varphi ,\theta }$  are defined differently (${\displaystyle \varphi }$  is one half of the rolling angle, ${\displaystyle \theta }$  is the parameter of the circle, whose chords are determined), for ${\displaystyle \varphi =\theta }$  one gets the same line. Hence any chord from the circle above is tangent to the nephroid and

• the nephroid is the envelope of the chords of the circle.

Nephroid as caustic of one half of a circle edit

The considerations made in the previous section give a proof for the fact, that the caustic of one half of a circle is a nephroid.

• If in the plane parallel light rays meet a reflecting half of a circle (see diagram), then the reflected rays are tangent to a nephroid.

Proof edit

The circle may have the origin as midpoint (as in the previous section) and its radius is ${\displaystyle 4}$ . The circle has the parametric representation

${\displaystyle k(\varphi )=4(\cos \varphi ,\sin \varphi )\ .}$ 

The tangent at the circle point ${\displaystyle K:\ k(\varphi )}$  has normal vector ${\displaystyle {\vec {n}}_{t}=(\cos \varphi ,\sin \varphi )^{T}}$ . The reflected ray has the normal vector (see diagram) ${\displaystyle {\vec {n}}_{r}=(\cos {\color {red}2}\varphi ,\sin {\color {red}2}\varphi )^{T}}$  and containing circle point ${\displaystyle K:\ 4(\cos \varphi ,\sin \varphi )}$ . Hence the reflected ray is part of the line with equation

${\displaystyle \cos {\color {red}2}\varphi \cdot x\ +\ \sin {\color {red}2}\varphi \cdot y=4\cos \varphi \ ,}$ 

which is tangent to the nephroid of the previous section at point

${\displaystyle P:\ (3\cos \varphi +\cos 3\varphi ,3\sin \varphi +\sin 3\varphi )}$  (see above).

Evolute edit

The evolute of a curve is the locus of centers of curvature. In detail: For a curve ${\displaystyle {\vec {x}}={\vec {c}}(s)}$  with radius of curvature ${\displaystyle \rho (s)}$  the evolute has the representation

${\displaystyle {\vec {x}}={\vec {c}}(s)+\rho (s){\vec {n}}(s).}$ 

with ${\displaystyle {\vec {n}}(s)}$  the suitably oriented unit normal.

For a nephroid one gets:

• The evolute of a nephroid is another nephroid half as large and rotated 90 degrees (see diagram).

Proof edit

The nephroid as shown in the picture has the parametric representation

${\displaystyle x=3\cos \varphi +\cos 3\varphi ,\quad y=3\sin \varphi +\sin 3\varphi \ ,}$ 

the unit normal vector pointing to the center of curvature

${\displaystyle {\vec {n}}(\varphi )=(-\cos 2\varphi ,-\sin 2\varphi )^{T}}$  (see section above)

and the radius of curvature ${\displaystyle 3\cos \varphi }$  (s. section on metric properties). Hence the evolute has the representation:

${\displaystyle x=3\cos \varphi +\cos 3\varphi -3\cos \varphi \cdot \cos 2\varphi =\cdots =3\cos \varphi -2\cos ^{3}\varphi ,}$ 

${\displaystyle y=3\sin \varphi +\sin 3\varphi -3\cos \varphi \cdot \sin 2\varphi \ =\cdots =2\sin ^{3}\varphi \ ,}$ 

which is a nephroid half as large and rotated 90 degrees (see diagram and section § Equations above)

Involute edit

Because the evolute of a nephroid is another nephroid, the involute of the nephroid is also another nephroid. The original nephroid in the image is the involute of the smaller nephroid.

The inversion

${\displaystyle x\mapsto {\frac {4a^{2}x}{x^{2}+y^{2}}},\quad y\mapsto {\frac {4a^{2}y}{x^{2}+y^{2}}}}$ 

across the circle with midpoint ${\displaystyle (0,0)}$  and radius ${\displaystyle 2a}$  maps the nephroid with equation

${\displaystyle (x^{2}+y^{2}-4a^{2})^{3}=108a^{4}y^{2}}$ 

onto the curve of degree 6 with equation

${\displaystyle (4a^{2}-(x^{2}+y^{2}))^{3}=27a^{2}(x^{2}+y^{2})y^{2}}$  (see diagram) .

• Arganbright, D., Practical Handbook of Spreadsheet Curves and Geometric Constructions, CRC Press, 1939, ISBN 0-8493-8938-0, p. 54.
• Borceux, F., A Differential Approach to Geometry: Geometric Trilogy III, Springer, 2014, ISBN 978-3-319-01735-8, p. 148.
• Lockwood, E. H., A Book of Curves, Cambridge University Press, 1961, ISBN 978-0-521-0-5585-7, p. 7.

• Mathworld: nephroid
• Xahlee: nephroid