In geometry, a generalized helicoid is a surface in Euclidean space generated by rotating and simultaneously displacing a curve, the ''profile curve'', along a line, its ''axis''. Any point of the given curve is the starting point of a circular

helix A helix () is a shape like a corkscrew or spiral staircase. It is a type of smooth space curve with tangent lines at a constant angle to a fixed axis. Helices are important in biology, as the DNA molecule is formed as two intertwined helic ...

. If the profile curve is contained in a plane through the axis, it is called the meridian of the generalized helicoid. Simple examples of generalized helicoids are the helicoids. The meridian of a helicoid is a line which intersects the axis orthogonally. Essential types of generalized helicoids are * ruled generalized helicoids. Their profile curves are lines and the surfaces are ruled surfaces. *circular generalized helicoids. Their profile curves are circles. In mathematics helicoids play an essential role as

minimal surfaces In mathematics, a minimal surface is a surface that locally minimizes its area. This is equivalent to having zero mean curvature (see definitions below). The term "minimal surface" is used because these surfaces originally arose as surfaces tha ...

. In the technical area generalized helicoids are used for staircases, slides, screws, and pipes.

Analytical representation

Screw motion of a point

Moving a point on a screwtype curve means, the point is rotated and displaced along a line (axis) such that the displacement is proportional to the rotation-angle. The result is a circular

. If the axis is the ''z''-axis, the motion of a point

P_0=(x_0,y_0,z_0)

can be described parametrically by :

\mathbf p(\varphi)=
\begin
x_0\cos \varphi -y_0\sin\varphi\\
x_0\sin \varphi +y_0 \cos \varphi\\
z_0 + c\; \varphi
\end \ , \ \varphi \in \R \ .

c\ne 0

is called ''slant'', the angle

\varphi

, measured in radian, is called the ''screw angle'' and

h=c\;2\pi

the ''pitch'' (green). The trace of the point is a ''circular helix'' (red). It is contained in the surface of a

right circular cylinder A cylinder (from ) has traditionally been a three-dimensional solid, one of the most basic of curvilinear geometric shapes. In elementary geometry, it is considered a prism with a circle as its base. A cylinder may also be defined as an infin ...

. Its radius is the distance of point

P_0

to the ''z''-axis. In case of

c>0

, the helix is called ''right handed''; otherwise, it is said to be ''left handed''. (In case of

c=0

the motion is a rotation around the ''z''-axis.)

Screw motion of a curve

The screw motion of curve :

\mathbf x(t)= (x(t),y(t),z(t))^T, \ t_1\le t\le t_2 \ ,

yields a generalized helicoid with the parametric representation *

\mathbf S(t,\varphi)=
\begin
x(t)\cos \varphi -y(t)\sin\varphi\\
x(t)\sin \varphi +y(t) \cos \varphi\\
z(t)+c\;\varphi
\end\ ,\quad t_1\le t\le t_2, \ \varphi \in \R \ .

The curves

\mathbf S(t=\text,\varphi)

are circular helices.
The curves

\mathbf S(t,\varphi=\text)

are copies of the given profile curve. Example: For the first picture above, the meridian is a ''parabola''.

Ruled generalized helicoids

Types

If the profile curve is a line one gets a ''ruled generalized helicoid''. There are four types: :(1) The line intersects the axis orthogonally. One gets a helicoid (''closed right'' ruled generalized helicoid). :(2) The line intersects the axis, but ''not'' orthogonally. One gets an oblique closed type. If the given line and the axis are skew lines one gets an open type and the axis is not part of the surface (s. picture). :(3) If the given line and the axis are skew lines and the line is contained in a plane orthogonally to the axis one gets a right open type or shortly open helicoid. :(4) If the line and the axis are skew and the line is ''not'' contained in ... (s. 3) one gets an oblique open type. Oblique types do ''intersect themselves'' (s. picture), ''right'' types (helicoids) do not. One gets an interesting case, if the line is skew to the axis and the product of its distance

d

to the axis and its slope is exactly

c

. In this case the surface is a

tangent developable In the mathematical study of the differential geometry of surfaces, a tangent developable is a particular kind of developable surface obtained from a curve in Euclidean space as the surface swept out by the tangent lines to the curve. Such a surf ...

surface and is generated by the directrix

(d\cos \varphi,d\sin\varphi,c\varphi)

. ''Remark:'' # The (open and closed) helicoids are Catalan surfaces. The closed type (common helicoid) is even a

conoid In geometry a conoid () is a ruled surface, whose rulings (lines) fulfill the additional conditions: :(1) All rulings are parallel to a plane, the '' directrix plane''. :(2) All rulings intersect a fixed line, the ''axis''. The conoid is a ri ...

#Ruled generalized helicoids are not algebraic surfaces.

On closed ruled generalized helicoids

A closed ruled generalized helicoid has a profile line that intersects the axis. If the profile line is described by

(t,0,z_0+m\;t)^T

one gets the following parametric representation *

\mathbf S(t,\varphi)=\begin
t\cos \varphi\\
t\sin \varphi\\
z_0+mt+c\varphi
\end\ .

m=0

(common helicoid) the surface does ''not'' intersect itself.
If

m\ne0

(oblique type) the surface intersects itself and the curves (on the surface) :

\mathbf S(t_i,\varphi)

with

t_i=\frac(2i+1), \ i=1,2,\ldots

consist of ''double points''. There exist infinite double curves. The smaller

, m,

the greater are the distances between the double curves.

On the tangent developable type

For the directrix (a helix) :

\mathbf x(\varphi)=(r\cos \varphi,r\sin \varphi,c\varphi)^T

one gets the following parametric representation of the tangent developable surface: *

\mathbf S(t,\varphi)=\mathbf x(\varphi)+t\mathbf \dot x(\varphi)=
\begin
r\cos \varphi-tr\sin\varphi\\
r\sin \varphi+tr\cos\varphi\\
c(t+\varphi)
\end\ .

The surface normal vector is :

\mathbf n =\mathbf S_t\times\mathbf S_\varphi=\mathbf \dot x\times(\mathbf \dot x+t\mathbf \ddot x)=t(\mathbf \dot x\times\mathbf \ddot x)=t
\begin
cr\sin\varphi\\
-cr\cos\varphi\\
r^2
\end\ .

For

t=0

the normal vector is the null vector. Hence the directrix consists of singular points. The directrix separates two regular parts of the surface (s. picture).

Circular generalized helicoids

There are 3 interesting types of circular generalized helicoids: :(1) If the circle is a meridian and does not intersect the axis (s. picture). :(2) The plane that contains the circle is orthogonal to the helix of the circle centers. One gets a pipe surface :(3) The circle's plane is orthogonal to the axis and comprises the axis point in it (s. picture). This type was used for baroque-columns. Uni-Mannheim Neubau Rettungsleiter.jpg, staircase, University Mannheim, Germany Rutsche Salinarium.jpg, pipe slide Salinarium St Pankratius P7250050.JPG, altar (1688), St. Pankratius, Neuenfelde, Germany

External links

Gfrerrer: ''Kurven und Flächen'', S. 47mathcurve.com: circular generalized helicoidmathcurve.com: developable generalized helicoidmathcurve.com: ruled generalized helicoidK3Dsurf: 3d surface generator
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References

*Elsa Abbena, Simon Salamon, Alfred Gray: ''Modern Differential Geometry of Curves and Surfaces with Mathematica'', 3. edition, Studies in Advanced Mathematics, Chapman & Hall, 2006, , p. 470 *E. Kreyszig: ''Differential Geometry''. New York: Dover, p. 88, 1991. * U. Graf, M. Barner: ''Darstellende Geometrie.'' Quelle & Meyer, Heidelberg 1961, {{ISBN, 3-494-00488-9, p.218 * K. Strubecker: ''Vorlesungen über Darstellende Geometrie'', Vandenhoek & Ruprecht, Göttingen, 1967, p. 286 Surfaces