A NEW POTENTIAL FUNCTION FOR SELF INTERSECTING
GIELIS CURVES WITH RATIONAL SYMMETRIES
Yohan D. Fougerolle, Fr´ed´eric Truchetet
LE2i Laboratory, UMR CNRS 5158, University of Burgundy, 12 rue de la fonderie, 71200 Le Creusot, France
Johan Gielis
Genicap Lab BV, Wilheminaweg 1, 2042 NN, Zandwoort, The Netherlands
Keywords:
Gielis curves and surfaces, Implicit functions, Parametric functions, R-functions, Superquadrics, Symmetry.
Abstract:
We present a new potential field equation for self-intersecting Gielis curves with rational rotational symme-
tries. In the literature, potential field equations for these curves, and their extensions to surfaces, impose
the rotational symmetries to be integers in order to guarantee the unicity of the intersection between the
curve/surface and any ray starting from its center. Although the representation with natural symmetries has
been applied to mechanical parts modeling and reconstruction, the lack of a potential function for Rational
symmetry Gielis Curves (RGC) remains a major problem for natural object representation, such as flowers
and phyllotaxis. We overcome this problem by combining the potential values associated with the multiple
intersections using R-functions. With this technique, several differentiable potential fields can be defined for
RGCs. Especially, by performing N-ary R-conjunction or R-disjunction, two specific potential fields can be
generated: one corresponding to the inner curve, that is the curve inscribed within the whole curve, and the
outer -or envelope- that is the curve from which self intersections have been removed.
1 INTRODUCTION
Describing and modeling nature is fascinating and,
generally speaking, one of the most fundamental re-
search activities: whether to model physical behav-
iors or geometric structures, to describe or to recog-
nize natural shapes, every research community aims
at representing nature as accurately as possible. Clas-
sical models are largely based on isotropic spaces
with the Euclidean circle as (isotropic) unit circle.
In nature however, anisotropy is the rule and dif-
ferent ways of measuring or geometrizing exist. In
2003, halfway between the fields of botany and com-
puter graphics, Gielis et al. introduced the superfor-
mula (Gielis, 2003; Gielis et al., 2003), which can
be seen as a parametric formulation for generalized
circles or ellipses. Superellipses defining anisotropic
unit circles led to notion of Minkowski distances and
Minkowski geometry (Thompson, 1996). Superel-
lipses have been extended to superquadrics in (Barr,
1981), which have found numerous applications due
to the limited number of shape parameters and their
ability to represent objects ranging from diamonds,
cubes, spheres, and any intermediate shape. More
interestingly, the superformula is now spreading to
other fields. For instance, it has been used in re-
cent work to study constant mean curvature surfaces
for anisotropic energies (Koiso and Palmer, 2008), in
clustering and data mining in (Morales and Bobadilla,
2008), and in fluid dynamics in (Wang, 2008). Re-
cently, Natalini et al. have presented a numerical
algorithm to write down the explicit solution to the
Dirichlet problem for the Laplace equation in a star-
like domain (Natalini et al., 2008), and presented
closed form equations for various Gielis curves.
In 2005, based on the parametric formula pro-
posed in (Gielis, 2003), potential fields for 3D
Gielis surfaces have been proposed in (Fougerolle
et al., 2005). This representation has found appli-
cations for Gielis surface recovery for mechanical
parts (Bokhabrine et al., 2007). Unfortunately, one
of its major weakness is that the implicit field equa-
tions require the rotational symmetries to be integers.
Such a restriction can be tolerated when manufac-
tured objects are represented. Unfortunately, as ini-
tially remarked in (Gielis, 2003), some natural objects
90
D. Fougerolle Y., Truchetet F. and Gielis J.
A NEW POTENTIAL FUNCTION FOR SELF INTERSECTING GIELIS CURVES WITH RATIONAL SYMMETRIES.
DOI: 10.5220/0001798200900095
In Proceedings of the Fourth International Conference on Computer Graphics Theory and Applications (VISIGRAPP 2009), page
ISBN: 978-989-8111-67-8
Copyright
c
2009 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
(a) (b)
Figure 1: a) Rose sepals. b) RGC with m = 5/2 and n
1
=
n
2
= n
3
= 0.43.
require the rotational symmetries to be rational num-
bers. Such symmetries are found in the phyllotaxy
of plants. Leaves are arranged in a helical or spiral
way around the stem. In rose, leaves are arranged
around the stem in a 5/2 arrangement, meaning that
the sixth leave will be precisely abovethe first one and
the spacing between leaves is 144
◦
. In wild roses the
five petals are arranged in a plane, but the sepals in
the preceding (almost planar) whorl still show the he-
lical arrangement as they are still 144
◦
apart. This ar-
rangement can be seen using m = 5/2 in the superfor-
mula. It involves fusion of certain parts, while in the
center an open structure is created, giving rise to the
rose hip, as illustrated in Figure 1. Non-integer sym-
metries can be observed in biomolecules as well, e.g.
DNA and proteins in which non-integer symmetries
are observed frequently (Janner, 2001; Janner, 2005).
Complex objects that are defined as Boolean opera-
tions between multiple globally deformed Gielis sur-
faces can be modeled and reconstructed (Fougerolle
et al., 2005; Bokhabrine et al., 2007). To transcribe
the Boolean predicates between 3D Gielis surfaces
into analytical equations, R-functions have been em-
ployed. The strategy adopted in this paper uses the
same tools and concepts, i.e. we use radial dis-
tance functions to build a 2D potential field, and R-
functions for the transcription of Boolean combina-
tions into analytical equations. The difference is that
now we perform R-functions not to combine implicit
fields of several Gielis curves or surfaces, but the
multiple implicit values of the same rational Gielis
curve. Thus, we overcome the self-intersection issue
through an auto-R-function operation and build 2D
potential fields equation for RGCs, that can represent
for instance the envelope of the curve or its ”core”.
We present several advantages of this representation,
ranging from flower modeling, from global shape to
petals, and its potential for further research directions,
such as parameter recovery and/or optimization.
The structure of the rest of paper is as follows: in
section 2 we recall the initial parametric definition of
Gielis curves, surfaces, and their associated potential
fields. In section 3 we briefly present R-functions.
Using R-function and the initial Gielis formula, two
potential fields are presented for 2D RGCs in sec-
tion 4. Several strategies about extension to Rational
Gielis Surfaces are presented and discussed in section
5. We then present our future work and conclusions
in section 6.
2 GIELIS CURVES
In polar coordinates, the radius r(θ) of a Gielis curve
is defined by:
r(φ) =
1
n
1
r
1
a
cos
mφ
4
n
2
+
1
b
sin
mφ
4
n
3
, (1)
with n
i
∈ R
+
, and a, b, and m ∈ R
+
∗
. Parameters a
and b control the scale, m represents the number of
rotational symmetries, n
1
, n
2
, and n
3
are the shape co-
efficients. Regular polygons and superellipses can be
generated by setting the shape coefficients to specific
values as shown in (Gielis, 2003).
Gielis only proposed the parametric formulation
for 2D curves. In the case of closed non self-
intersecting curve (m is positive integer), for a 2D
point P(x, y) one can define the following potential
field:
F
1
(x,y) = 1−
k
−→
OPk
k
−→
OIk
= 1−
s
x
2
+ y
2
r
2
(θ)
. (2)
O is the center of the curve, and the point I =
r(θ(x,y)) corresponds to the intersection between the
curve and the half line [OP). If the symmetry param-
eter m is an integer, the intersection I is unique. If the
curve is closed, the sign of the potential field F(x,y)
generated by equation 2 can be used to define a par-
tition of the 2D space. In this case, the set of points
where F(x,y) is positive corresponds to the inside of
the Gielis curve, the set of points where F(x,y) is neg-
ative corresponds to its outside, and the curve corre-
sponds to the zero-set of the potential field.
In (Fougerolle et al., 2005), by setting a = b = 1 in
equation 1 and by considering a 3D Gielis surface as
the spherical product of two 2D Gielis curves, poten-
tial fields for 3D non self-intersecting Gielis surfaces
have been introduced as:
F
2
(x,y,z) = 1 −
1
r
2
(φ)
s
x
2
+ y
2
+ z
2
cos
2
φ
r
2
1
(θ) − 1
+ 1
. (3)
Such representation of Gielis surfaces as iso-values
of a potential field is crucial for Gielis surface recon-
struction from 3D data, because it is used to build var-
ious cost functions to be optimized.
A NEWPOTENTIAL FUNCTION FOR SELF INTERSECTING GIELIS CURVES WITH RATIONAL SYMMETRIES
91
3 R-FUNCTIONS
R-functions find their origin in geometric algebra
based on logic and have been introduced by Vladimir
Logvinovich Rvachev in (Rvachev, 1967). Since
their introduction, R-functions have found direct ap-
plications in several fields, such as geometric mod-
eling and boundary value problems. For concise-
ness purpose, we briefly present the most common R-
functions in this section. The reader is invited to refer
to the recent survey by Shapiro (Shapiro, 2007) for
more in depth presentation of R-functions and their
applications.
The simplest R-function is R
α
(x
1
,x
2
) and is de-
fined by:
R
α
(x
1
,x
2
) =
1
1+ α
x
1
+ x
2
±
q
x
2
1
+ x
2
2
− 2αx
1
x
2
,
(4)
where α(x
1
,x
2
) is an arbitrary symmetric function
such that −1 < α(x
1
,x
2
) ≤ 1. Setting α to 1 leads
to the simplest and most popular R-functions:
R-conjunction min(x
1
,x
2
) and R-disjunction
max(x
1
,x
2
). Other useful R-functions with dif-
ferential and normalization properties, namely
R
m
0
and R
p
, are studied in detail in (Shapiro and
Tsukanov, 1999), and are respectively defined by:
R
m
0
(x
1
,x
2
) =
x
1
+ x
2
±
q
x
2
1
+ x
2
2
x
2
1
+ x
2
2
m
2
,
(5)
where m is any even positive integer and
R
p
(x
1
,x
2
) = x
1
+ x
2
±
x
p
1
+ x
p
2
1
p
, (6)
for any even positive integer p. R
α
, R
m
0
, and R
p
func-
tions only handle two arguments. Rvachev introduced
the N-ary R-conjunction and R-disjunction to handle
more than two arguments, which are less restrictive
than R
α
, R
m
0
, and R
p
and more appropriate to RGCs.
The parameter m is an integer and corresponds to the
parameter used for R
m
functions.
i=n
^
i=1
(m)
x
i
≡
n
∑
i=1
(−1)
m
x
m
i
(x
i
−|x
i
|)+
n
∏
i=1
x
m
i
(x
i
+ |x
i
|).
(7a)
i=n
_
i=1
(m)
x
i
≡
n
∑
i=1
x
m
i
(x
i
+|x
i
|)−
n
∏
i=1
x
m
i
(−1)
m
(|x
i
| − x
i
).
(7b)
If no specific constraint about differentiability is re-
quired, m can be set to zero, which leads to the
simplified version of N-ary R-conjunction and R-
disjunction defined in equations 8a and 8b.
i=n
^
i=1
x
i
≡
n
∑
i=1
(x
i
−|x
i
|)+
n
∏
i=1
(x
i
+ |x
i
|). (8a)
(a) (b) (c) (d)
Figure 2: Examples of developing flower buds. a) Ochna at-
ropurpurea: Development of ovary. b) Greyia sutherlandii
stage 1: sepals protect the newly formed petals. c) Greyia
sutherlandii stage 2: stamens develop with petals in the five
corners of the pentagon (sepals removed). d) Greyia suther-
landii stage 3: stamens and pistils develop.
i=n
_
i=1
x
i
≡
n
∑
i=1
(x
i
+|x
i
|)−
n
∏
i=1
(|x
i
| − x
i
). (8b)
An R-function is a real-valued function character-
ized by some property that is completely determined
by the corresponding property of its arguments. More
specifically, the R-functions presented in this paper
have the property that their sign is completely deter-
mined by the signs of their arguments. In the follow-
ing section, we present how to use this property to
build a signed potential field for RGCs.
4 POTENTIAL FIELD EQUATION
FOR RATIONAL GIELIS
CURVES
While RGC curves with multiple crossings and period
k (with k even) can be studied in a XY graph without
intersections, it is worthwhile to develop a potential
field function which does take the intersections into
account and in which multiple function values do oc-
cur. As observed in rose, such intersections could in-
deed give rise to a center which can develop into the
rose hip. Alternatively, the multiple intersections can
lead to the separation of specific, isolated sectors in
which separate developmental processes may occur.
Such sectors are indeed observed using R-conjunction
of outer envelope and the complementary of the core
(Figure 5). At the bud stage, flower development in-
volves the sequential initiation of various whorls in
well-defined yet separated sectors. In Greyia suther-
landii (Figures 2(b), 2(c), and 2(d)) for example, af-
ter the formation of sepals in the ’corners’ petals are
formed and inbetween the formation of stamens oc-
curs.
We come back to the superformula initial formu-
lation and introduce rational symmetry: the symmetry
parameter m is no longer an integer and can be ratio-
nal, and a = b = 1. By definition, RGCs are self inter-
secting curves, i.e. the symmetry parameter m can be
GRAPP 2009 - International Conference on Computer Graphics Theory and Applications
92
Figure 3: Intersections between a RGC with m = 8/3 and a
half ray.
written as the ratio of two integers as m = p/q. The
parametric formulation of a RGC is then written as:
r(φ) =
1
n
1
r
cos
pφ
4q
n
2
+
sin
pφ
4q
n
3
, (9)
with p,q ∈ N
+
∗
. The parameter p is similar to m,
i.e. still represents the rotational symmetry number.
The parameter q corresponds to the maximum num-
ber of self intersections, and the angle θ now belongs
to [0,2qπ]. The condition for a RGC to be closed is to
verify that the radius r(θ) is identical for angles θ = 0
and θ = 2qπ, which can be written as r(0) = r(2qπ).
Figure 3 shows an example of a RGC with p = 8
and q = 3. For a given RGC, there exist multiple in-
tersections between a ray originated from its center
and the curve, i.e. there exist multiple polar coordi-
nates in [0,2qπ] that generate points lying both on the
curve and the ray, as illustrated in Figure 3, where
three intersections, noted I
1
,I
2
and I
3
are detected.
The number of intersections depends on q and double
intersection points appear for angles θ = kp/q. For a
given point P(x,y), a first angle θ
0
within [0,2π] can
be easily determined. The corresponding intersection
point I
0
can be computed as r(θ
0
). Other angles θ
k
and corresponding intersection points I
k
can easily be
determined using θ
k
= θ
0
+ 2kπ and I
k
= r(θ
k
). We
see that the several intersections can be simply com-
puted and correspond to the multiple values of the ra-
dius for θ
0
+ 2kπ values. For each intersection point
I
k
, equation 2 can be applied to associate a potential.
Now, the last problem to overcome is to build a
continuous potential field from these k individual po-
tentials. One of the simplest idea is to consider the
maximum or minimum potential determined for in-
tersection points I
k
using equation 4 with α = 1. This
approach generates a potential field that is not smooth
everywhere, as illustrated in Figures 4(b),4(d), 4(f),
4(h), that have been obtained using min and max
R-functions. Therefore, such a technique suffers a
severe drawback, especially for reconstruction pur-
poses, where differentiable functions are often pre-
ferred. To obtain a differentiable potential field, we
can combine each potential using R-functions pre-
sented in equations 5 or 6. Using R
p
may be an ad-
vantage if normalization property is desired, but it
also has a major drawback. With R
p
-functions, the
generated potential field depends on the order the R-
functions. Indeed, for instance, it is easy to verify that
(x
1
∧x
2
)∧ x
3
6= x
1
∧(x
2
∧x
3
), except over its zero-set.
Unicity of the potential field can be obtained using
two techniques: sort individual values or restrict the
q parameter to be set to 2 to keep binary R-functions,
which is not satisfactory in both cases. Fortunately,
for multiple self intersections, n potential values can
be combined using n-ary R-functions as defined in
equation 7. The justification for the introduction of
equations 8a and 8b now clearly appears: using bi-
nary R-functions, such as R
α
, R
p
or R
m
, restricts the
parameter q in equation 9 to be equal to 2, whereas
with N-ary R-functions q ∈ N
+
∗
. The commutativity
of N-ary R-functions is obvious since these functions
are a sum of sums and products that are commutative.
Eventually, by replacing the arguments of equa-
tions 8a and 8b by the potential field defined in equa-
tion 2, we obtain the inner and outer potential fields
for 2D-RGCs, respectively defined by:
i=q
^
i=1
F
1
(x
i
,y
i
) and
i=q
_
i=1
F
1
(x
i
,y
i
), (10)
where F
1
(x
i
,y
i
) corresponds to the potentials evalu-
ated for the multiple intersection points (x
i
,y
i
) using
equation 2 combined through N-ary R-conjunction
and R-disjunction, respectively. Figure 4 illustrates
the relative intensity of the potential field for various
RGCs and several R-functions.
(a) using Eq.8b (b) using R
α
(c) using Eq.8a (d) using R
α
(e) using Eq.8b (f) using R
α
(g) using Eq.8a (h) using R
α
Figure 4: Color coding of relative intensity of the potential
field generated by auto R-function of a RGC with a = b = 1,
n
1
= 0.5, n
2
= n
3
= 3.5, p = 5. The RGC is in dark red.
First row: m = 5/2. Second row m = 5/3. From left
to right: relative potential field intensity using the N-ary
R-disjunction, Maximum, N-ary R-conjunction, and Mini-
mum.
Additionally, the inner and outer potential fields
A NEWPOTENTIAL FUNCTION FOR SELF INTERSECTING GIELIS CURVES WITH RATIONAL SYMMETRIES
93
can be combined together, for example to represent
developmental processes in flowers. For instance, one
can want to perform the equivalentof the Boolean dif-
ference between the inner and outer curve, simply by
using binary R-functions, as illustrated in Figure 5.
Such a representation finds direct biological meaning:
when a plant goes into flowering, the flower approxi-
mately becomes a planar structure, going from a spiral
phyllotaxy(givenby Fibonaccinumbers) into a planar
phyllotaxy or still with helical or spiral tendencies.
But in a meristem of the flower, new entities have to
develop sequentially (first sepals, followed by petals,
stamen and finally pistil). This means that in a pla-
nar arrangement a clear separation of areas/sectors is
necessary, as delineation of potential fields. And that
is precisely what distinguishes Figures 4 and 5. This
illustrates the potential of our approach to build from
bottom up (pure R-functions/logic, with RGC) a way
of modeling flowers. This example also illustrates the
strength of our approach, thanks to R-functions, be-
cause such sectors may not be represented using Na-
talini’s approach.
(a) p = 5,q = 2 (b) p = 5,q = 3 (c) p = 5,q = 4
(d) p = 5,q = 2 (e) p = 5,q = 3 (f) p = 5,q = 4
Figure 5: R-conjunction between a RGC outer envelope and
the complementary of its inner envelope to represent vari-
ous petal shapes. First row: using R
p
-function. Second row:
using R
α
.
5 EXTENSION TO RATIONAL
GIELIS SURFACES
We present two approaches to extend RGCs to Ra-
tional Gielis Surfaces (RGSs). The first one is using
spherical product, and the second is building revo-
lution surfaces using a RGC and a profile. The ob-
jective of 3D extension through spherical product is
to generate a closed surface built upon two Gielis
curves, which can be used in solid modeling for ex-
ample. This operation requires one important restric-
(a) (b)
Figure 6: Rational Gielis Surfaces. a) Spherical product. b)
Revolution surface.
tion: the second generating curve cannot be ratio-
nal. The main problems arising when considering
a RGC as second generating curve are surface gen-
eration/continuity and potential field evaluation. In
spherical product, half of the second curve, that cor-
responds to angles φ ∈ [−
π
2
,
π
2
], is rotated around the
rotation axis of the first generating curve. In this case,
the 2qπ modulus to evaluate every intersection leads
to curve discontinuities, which is a major problem
for efficient and simple tesselation algorithms and po-
tential field evaluation. Thus, one solution to build
closed surfaces while preserving surface continuity
and signed implicit field definition, is to perform the
spherical product between one RGC with one GC.
The implicit field generated can then be evaluated by:
i=q
^
i=1
F
2
(x
i
,y
i
) and
i=q
_
i=1
F
2
(x
i
,y
i
), (11)
where F
2
(x,y) is the potential equation for 3D
Gielis Surfaces presented in equation 3. An example
of a mesh corresponding to such surface is illustrated
in Figure 6(a).
The second approach consists in defining a pro-
file, by any known techniques such as NURBS for
instance, and to use this profile as an elevation pro-
file. In this case, the surface created does not define
a closed object, which makes impossible the expres-
sion of an implicit field. Nevertheless, such represen-
tation may be very useful for compact and efficient
representation of elementary 3D flower patterns, es-
pecially in entertainment or video-game industry. An
example of a revolution surface using RGC, using a
cubic polynomial profile, is presented in 6(b).
6 CONCLUSIONS
We have presented new potential functions for closed
Rational Gielis Curves and possible strategies for
their extension to 3D surfaces. Our approach makes
use of R-functions to overcome the self-intersections
GRAPP 2009 - International Conference on Computer Graphics Theory and Applications
94
issue introduced by the rational rotational symmetry.
With this technique, several differentiable potential
fields can be defined for RGCs and, more specifi-
cally, one corresponding to the inner curve, that is the
curve inscribed within the whole curve, and one cor-
responding to the envelope. Such representation of-
fers promising perspectives, especially in botany with
classification and morphology metrics: as illustrated
in Figure 5, combining inner and outer potential fields
through R-functions leads to the definition of sectors
that are directly related to the flower developmental
process.
Among the numerous other research directions,
we consider the study of other possible 3D extensions
and their applications to solid modeling, boundary
value problems, and/or entertainment (fast 3D flower
modeling and rendering, procedural flower field tex-
ture generation, etc). Another still highly challeng-
ing research concerns the shape and symmetry pa-
rameters recovery. To our knowledge, in the lit-
erature, there still exist very few papers dedicated
to Gielis curves parameters recovery using integer
symmetries, and none considering rational symme-
tries. The introduction of potential equations for such
closed curves therefore opens new research perspec-
tives in this field. Moreover, due to the complexity of
the space parameters, deterministic methods, such as
Levenberg-Marquardt method, can only be applied in
restricted cases, with prior symmetry detections and
strong assumptions. Our current and future works
include the development of more suitable RGC po-
tential functions for optimization processes combined
with the study of appropriate stochastic algorithms for
efficient RGCs parameters recovery and their applica-
tion to classification, pattern recognition, and object
segmentation both in 2D and 3D.
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A NEWPOTENTIAL FUNCTION FOR SELF INTERSECTING GIELIS CURVES WITH RATIONAL SYMMETRIES
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