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Derivation of (a) frieze mm; (b) ornament pmm from generating rosette with the symmetry group D2. |
However, an almost equal role in the formation of
different ornamental motifs belongs to the reverse
desymmetrization procedure, a way which mainly leads from the
maximal symmetry groups generated by reflections,
characterized by a high degree of visual and constructional
simplicity, to their subgroups. The results obtained are
subgroups belonging to the same category as a group undergoing
desymmetrization, or its subgroups with invariant subspace(s) of
lower dimension(s) (e.g., the symmetry groups of friezes G21
as line subgroups of the symmetry groups of ornaments G2).
At first restricted to the maximal groups of symmetry generated
by reflections, to the regular tessellations or Bravais lattices,
the desymmetrization method in painting becomes in time, firstly
thanks to the use of colors, an efficient procedure for deriving
all symmetry groups as subgroups of wider groups. Under the term
"desymmetrization" of certain symmetry group we understand this
as the procedure beginning with the elimination of corresponding
symmetries and resulting in the derivation of certain subgroup
H of the given group. In line with this, every desymmetrization
is defined by the group G and its subgroup H, i.e. by the
group/subgroup symbol G/H. The reverse procedure, resulting in
some supergroup of the given group G, is called
symmetrization (group extension).
Within the desymmetrization method, we can, depending on
the desymmetrization means used, distinguish classical-symmetry
(non-colored), antisymmetry and color-symmetry
desymmetrizations. Under the
term "classical-symmetry
desymmetrization" (non-colored desymmetrization) we will discuss
all desymmetrizations realized, for example, by using an
asymmetric figure belonging to the fundamental region, or by
deleting their boundaries and joining two or more adjacent
fundamental regions, etc. The term "non-colored" used as the
alternative for "classical-symmetry", should not be understood
literally, since it does not prohibit the use of colors or some
of their equivalents (e.g., indexes), but includes as well, all
other cases where colors have been used for a desymmetrization
without resulting in some antisymmetry or color-symmetry group.
In the same sense we will use the term "classical theory of
symmetry" which denotes the theory of symmetry without its
generalizations - antisymmetry and colored symmetry. The term
"external desymmetrization" will be used to denote a
desymmetrization achieved by varying boundaries of a fundamental
region (Figure 1.16b).
(a) Generating rosette with the symmetry group D4; (b)
its external desymmetrization D4/C4; (c)
antisymmetry group D4/C4.
Let e1 be an antiidentity transformation which
satisfies the relations: e12 = E e1S = Se1, where S is
any symmetry transformation. The transformation S' = e1S is then
called an antisymmetry transformation. As the
interpretation of the transformation e1, it is possible to
accept the alternating change of any bivalent quality, geometric
or not, which commutes with symmetries, e.g., the color change
black-white, change of electricity charges +, -, etc. A group
which besides symmetry transformations contains antisymmetry
transformations is called an antisymmetry group. As the
basis for deriving antisymmetry groups we take some symmetry
group G which we call a generating group of antisymmetry
(or simply a generating group). By replacing the symmetries
(generators) of the group G by antisymmetries (antigenerators)
we obtain, as a result, an antisymmetry group G' which,
depending upon whether the antiidentity transformation e1 is
the element of the group G' or not, is called a senior
(neutral, gray) or a junior (black-white)
antisymmetry group respectively. Every senior antisymmetry group
has the form G' = G×{e1} = G×C2, where the
group generated by e1 is denoted by {e1}. All junior
groups are isomorphic with their generating group G. Every
junior antisymmetry group is uniquely defined by the generating
group G and by its subgroup H of the index 2. From there
originated the group/subgroup symbols G/H of junior
antisymmetry groups, where the relationship G/H @ C2 holds
(Figure 1.16c). Since all (normal) subgroups of the index 2 of
the generating group G can be obtained knowing junior
antisymmetry groups derived from G, antisymmetry is included
in the desymmetrization method. Besides a large field of application
in Physics, various interpretations of the antiidentity
transformation as a geometric transformation which commutes with
all the symmetries of the generating group, make possible the
dimensional transition from the symmetry groups of the n-
dimensional space to those of the (n+1)-dimensional space. For
example, the symmetry groups of bands G321 can be
derived by using antisymmetry from the symmetry groups of
friezes G21, the symmetry groups of layers G32
from the symmetry groups of ornaments G2, etc. Corresponding
black-white antisymmetry plane motifs (so-called Weber
diagrams or antisymmetry mosaics) can be understood as
adequate visual interpretations of the symmetry groups of bands
G321 or layers G32, where the transformation e1 -
color change black-white is identified with the plane reflection
in the invariant plane of the generating frieze or ornament
(Figure 1 .17).
Weber diagrams of bands.
The first antisymmetry ornamental motifs are found in
Neolithic ornamental art with the appearance of two-colored
ceramics and for centuries have represented a suitable means for
expressing the dualism, internal dynamism, alternation, with a
distinct space component - a suggestion of the relationships
"in front-behind", "above-below", "base-ground",¼
The next generalization of antisymmetry is the
polyvalent, colored symmetry with the number of "colors"
N ³ 3, where each color is denoted by the corresponding index
1,2,¼,N. A permutation of the set
{1,2,¼,N} is any one-to-one mapping of this set onto itself. Let PN be
a subgroup of the symmetric permutation group SN (or
simply symmetric group), i.e. of the group of all the
permutations of the set {1,2,¼,N}, c Î PN and
cS = Sc, where S is a symmetry transformation, an element of the
symmetry group G. Then S* = cS is called a colored
symmetry transformation. A color permutation c can be
interpreted as a change of any polyvalent quality which commutes
with symmetries S Î G. A colored symmetry group is a
group which besides symmetry transformations contains colored
symmetry transformations (or colored symmetries). By analogy to
antisymmetry groups, the symmetry group G is called a
generating group of colored symmetry. The colored symmetry group
G* derived from G is called a junior colored
symmetry group iff it is isomorphic with G. In this work only
junior colored symmetry groups are discussed. Every junior
colored symmetry group can be defined by the ordered pair (G,H)
which consists of the group G and its subgroup H of the index
N, i.e. [G:H] = N. Two groups of colored symmetry (G,H) and
(G',H') are equal if there exists an isomorphism i(G) = G'
which maps H onto H'
(R.L.E. Schwarzenberger, 1984). For
N = 2 and PN = C2, (G,H) is an antisymmetry group. A color
permutation group PN is called regular if it does not
contain any transformation, distinct from the identity
permutation, which keeps invariant an element of the set
{1,2,¼,N}. If it contains such a transformation, a color
permutation group is called irregular. Depending upon
whether the color permutation group PN is regular or not, we
can distinguish two cases. For a regular group PN every
colored symmetry group is uniquely defined by the generating
group G and its normal subgroup H of index N - the
symmetry subgroup of G*. This results in the
group/subgroup symbols of the colored symmetry groups G/H, and
[G:H] = N (Figure 1.18a). For the irregular group PN,
besides G and H we must consider also the subgroup H1 of
the group G*, which maintains each individual index
(color) unchanged (i.e. group of stationariness of colors). In
this case H is not a normal subgroup of G. The order of the
group PN is NN1, where [G:H] = N, [H:H1] = N1 and quotient
group G/H1 @ PN. To denote such colored symmetry groups,
the symbols G/H/H1 are used (Figure 1.18b).
(a) Colored symmetry group C4/C1; (b)
D4/D2/C1.
By interpreting "colors" as physical polyvalent
properties commuting with every transformation of the generating
symmetry group, it is possible to extend considerably the domain
of the application of colored ornaments treated as a way of
modeling symmetry structures - subjects of natural science
(Crystallography, Physics, Chemistry, Biology¼). As an
element of creative artistic work, although being in use for
centuries, colored symmetry can be, taking into consideration the
abundance of unused possibilities, a very inspiring region. We
find proof of this in the works of M.C. Escher (M.C. Escher,
1971a, b). On the other hand, the various applications of colors
in ornaments, e.g., ornamental motifs based on the use of colors
in a given ratio, by which harmony - balance of colors of
different intensities - is achieved, have yet to find their
mathematical interpretation. Accepting "color" as a geometric
property, and colored transformations as geometric
transformations which commute with the symmetries of the
generating group, has opened up a large unexplored field for the
theory of colored symmetry. This was made clear in the recent
works discussing multi-dimensional symmetry groups, curvilinear
symmetries, etc. (A.M. Zamorzaev, Yu.S. Karpova, A.P. Lungu,
A.F. Palistrant, 1986).
The results of the theory of antisymmetry and colored
symmetry can be used also for obtaining the minimal indexes
of subgroups in the symmetry groups. As opposed to the finite
groups, where for the index of the given subgroup there is
exactly one possibility, in an infinite group the same subgroup
may have different indexes. For example, considering a frieze
with the symmetry group 11, generated by a translation X,
and its colorings by N = 2,3,4,¼ colors, where the group of
color permutations is the cyclic group CN of the order N,
generated by the permutation c = (123¼N), the result of
every such a color-symmetry desymmetrization is the symmetry
group 11, i.e. the colored symmetry group 11/
11. Therefore, we can conclude that the index of the subgroup
11 in the group 11 is any natural number N and that
its minimal index is two. The results of computing the (minimal)
indexes of subgroups in groups of symmetry, where the subgroups
belong to the same category of symmetry groups as the groups
discussed, based on the works of H.S.M. Coxeter and W.O.J. Moser
(H.S.M. Coxeter, W.O.J. Moser 1980;
H.S.M. Coxeter 1985, 1987)
are completed with the results obtained by using antisymmetry and
colored symmetry. They are given in the corresponding tables of
(minimal) indexes of subgroups in the symmetry groups. Besides
giving the evidence of all subgroups of the symmetry groups,
these tables can serve as a basis for applying the
desymmetrization method, because the (minimal) index is the
(minimal) number of colors necessary to achieve the corresponding
antisymmetry and color-symmetry desymmetrization. For denoting
subgroups which are not normal, italic indexes are used (e.g.,
3).
It is not necessary to set apart antisymmetry from
colored symmetry, since antisymmetry is only the simplest case of
colored symmetry (N = 2), but their independent analysis has its
historical and methodical justification, because bivalence is the
fundamental property of many natural and physical phenomena
(electricity charges +, -, magnetism S, N, etc.) and of human
thought (bivalent Aristotelian logic). In ornamental art,
examples of antisymmetry are mainly consistent in the sense of
symmetry, while consistent use of colored symmetry is very rare,
especially for greater values of N.
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