Prior to embarking on our odyssey to comprehend the abstract expressions and finer intricacies of group theory, we shall first analyze the simpler concepts of symmetry.

Now, humans are endowed with an intuitive understanding of what “symmetry” denotes. All around we are literally surrounded by objects – some display no features of symmetry whatsoever, while others exhibit clear evidence of symmetry that is intrinsically recognized by humans [1]. In fact, during the course of our evolution as a species, symmetry has grown intimately intertwined with the very concept of beauty itself [2]. Whatever is symmetric in nature appears beautiful to the human eye.

In the realm of decorative arts, one may mention the works of the prolific Nordic-Dutch lithographer Maurice Escher [4]. Including dazzling outpourings of geometrical splendour exhibiting a perplexing interplay of different symmetries and optical illusions such as “Air and Water” (1938) or “Ascending and Descending” (1960), his Netherlandish productions have a special appeal for physicists and mathematicians.

The performing arts also exhibit a marked fondness for symmetry. For example, poets have always waxed eloquent about the beauty of symmetry and have always turned lyrical regarding the rhythm of rhyme. For example, a poem written by Su Dongpo (eleventh century) in China, consisting of eight vertical lines of seven characters each. The poem can be read forward and backward each time with correct rhyme and meter. In this context, one must remember that the hoary Chinese language is read commencing from right, top-down a column, and then down along the second column and so forth.

Musicians too are not far behind in seeking beauty from symmetry. For example, the Crab Canon of the Nordic-German musician J. S. Bach (seventeenth century) is a violin duet where each voilin’s music is a time reversed-version of that of the other violin.

So clearly symmetry and its intrinsic beauty has been the focus of much human creative endeavour among artists. The same can be said of scientists too. The first motivation, more as an act of intellectual satisfaction, is for seeking beauty for its own sake

In fact, the search for symmetry in nature – with symmetry being sought for its own sake – has been found to be an extremely fruitful enterprise by scientists. First we study symmetry as a scientific concept, and thereafter move over to group theory, which is the mathematical language that incorporates symmetry in a consistent manner.

To understand symmetry, let us consider figures drawn on a page. Symmetry of a figure exists if the shape it represents does not change in size or layout when subjected to a rotation or reflection within itself. These changes are termed transformations. A “no-change” is indeed a transformation of a special kind itself, and is denominated as an identity. Just as multiplication by unity does not alter the value of a quantity, so in the case of symmetry, the value of symmetry does not change when the identity participates.

In Figure 1.1(a),(b), the figure (denoting a neck – tie) before and after the transformation appears the same. Hence, it is symmetric under the reflection transformation.

Note that a rotation by 6π3=2π returns Figure 1.1(c) to the original configuration. So the cycle is repeated. All the more reason that the “identity” is a transformation. Note that points 1, 2, 3 are external labels (not existing on the figure itself) and hence the figures under all the above three transformations Figure 1.1(c),(d),(e) – appear the same, or are in fact identical. Hence these entities are symmetric under these transformations.

Figure 1.2(a) provides a rough idea of symmetry. Essentially, symmetry involves some entity. This entity retains its identity when a...