An earliest preoccupation of man has been to find ways of partitioning infinite space into regions having a finite number of distinct shapes and yielding beautiful patterns called tiling. Archaeological edifices, everyday objects of use like baskets, carpets, textiles, etc. and many biological systems such as beehives, onion peels and spider webs also exhibit a variety of tiling. Escher’s classical paintings have not only given a new dimension to the artistic value of tiling but also aroused the curiosity of mathematicians. The generation of aperiodic tiling with five-fold rotational symmetry by Penrose in 1974 and the more recent production of decorated pentagonal tiles by Rosemary Grazebrook have heightened the interest in the subject among artists, engineers, biologists, crystall ographers and mathematicians1–5. In spite of its long history, the subject of tiling is still evolving. In this communication, we propose a novel algorithm for the growth of a Penrose tiling and relate it to the equally fascinating

subject of fractal geometry pioneered by Mandelbrot6.

The algorithm resembles those for generation of fractal

objects such as Koch’s recursion curve, Peano curve,

etc. and enables consideration of the tiling as cluster

growth as well. Thus it clearly demonstrates the dual

nature of a Penrose tiling as a natural and a nonrandom

fractal

Ramachandrarao, P

Sanyal, D

Sinha, Arvind

English

eprints@NML

RESEARCH COMMUNICATIONSCURRENT SCIENCE, VOL. 79, NO. 3, 10 AUGUST 2000364On the fractal nature of Penrose tilingP. Ramachandrarao*, Arvind Sinha and D. SanyalNational Metallurgical Laboratory, Jamshedpur 831 007, IndiaAn earliest preoccupation of man has been to findways of partitioning infinite space into regions havinga finite number of distinct shapes and yielding beauti-ful patterns called tiling. Archaeological edifices, every-day objects of use like baskets, carpets, textiles, etc.and many biological systems such as beehives, onionpeels and spider webs also exhibit a variety of tiling.Escher’s classical paintings have not only given a newdimension to the artistic value of tiling but alsoaroused the curiosity of mathematicians. The gener-ation of aperiodic tiling with five-fold rotationalsymmetry by Penrose in 1974 and the more recentproduction of decorated pentagonal tiles by RosemaryGrazebrook have heightened the interest in the subjectamong artists, engineers, biologists, crystallographersand mathematicians1–5. In spite of its long history, thesubject of tiling is still evolving. In this communica-tion, we propose a novel algorithm for the growth of aPenrose tiling and relate it to the equally fascinatingsubject of fractal geometry pioneered by Mandelbrot6.The algorithm resembles those for generation of fractalobjects such as Koch’s recursion curve, Peano curve,etc. and enables consideration of the tiling as clustergrowth as well. Thus it clearly demonstrates the dualnature of a Penrose tiling as a natural and a non-random fractal.THE aperiodic tilings have many interesting propertieswhich can be illustrated with respect to the most discussedquasi-periodic tiling: the Penrose tiling7. These can beinfinite in number. The tilings exhibit local isomorphismwhich ensures that every finite region in any one tiling iscontained somewhere inside every other and that too infi-nitely many times. The tilings can be generated from oneanother by the methods of inflation or deflation. Forexample, in deflation a cluster of tiles is subdivided intosmaller pieces following specific procedures. Performingsuch operations iteratively, one can generate an aperiodictiling with a much larger number of smaller tiles. Theseprocedures endow the tiling with the property of self-similarity. These properties have suggested, right from thetime of the discovery of Penrose tilings, that the tiling isfractal in nature2. If so, it should be possible to generatethe tiling by an algorithm that is characteristic of fractalgeneration and consisting of the three steps of initiation,generation and cascade at all scales. Till date, there are nomethods of generating a Penrose tiling in a fashion similarto the generation of a non-random fractal object. Wepostulate, in this communication, such an algorithm andarrive at the Hausdorff fractal dimension.  Let us consider a figure in the form of two straightedges AB and BC of equal length, a, and intersecting eachother at an angle of 108° (Figure 1 a). The point of inter-section, B, is called a vertex. Divide the side AB in theratio τ : 1, as seen from A, and replace a short segmentwith an isosceles triangle having sides BE and ED oflength a/τ. The triangle should be erected such that*For correspondence. (e-mail: dnml@csnml.ren.nic.in)Figure 1.  Proposed algorithm for the generation of a Penrose tiling.a, the initiator; b, the first generation (n = 1); c, the second generation(n = 2); and d, Penrose tiling in a thick rhomb: n = 7.cdbaCH COMMUNICATIONSRESEARCH COMMUNICATIONSCURRENT SCIENCE, VOL. 79, NO. 3, 10 AUGUST 2000 365the angle at B is divided in the ratio 2 : 1 and∠EDB = ∠EBD = 72° each. τ is the golden mean and hasthe value of (1 +    )/2. Next join the point E to C whichlies at a distance of a/τ as well. We may now erase allother lines which do not have a length a/τ (Figure 1 b).These steps generate three line segments of equal length(DE, EB and EC) and two new vertices D and E with∠ADE and ∠BEC being 108°. It may be noted that one ofthese angles is exterior to the apex of the isosceles tri-angle erected, while the other is exterior to its base. Thesetwo angles are once again divided as before by erectingtwo isosceles triangles of side a/τ2 such that two adjacentangles of 36° each are formed at the apex and two adja-cent angles of 72° form at the base of the previouslyerected isosceles triangle. All vertices at a distance of a/τ2will then be joined and all segments whose length isnot a/τ2 will be erased (Figure 1 c). The two isosceles tri-angles erected in this operation are EFG and DHI. It maybe seen that the rhombi BDHI and BIEF are the thin andthick rhombi used by Penrose to generate an aperiodictiling. The newly formed vertices with an included angleof 108° are at F, G, H and I. The angle EIB is also 108°.The procedure described above can be repeated to divideall the 108° angles by erecting isosceles triangles of side1/τ of the side on which they are being erected. We alsojoin the newly formed vertices to already existing verticesat a distance equal to the side of the triangle erected. Theprocedure can be repeated ad infinitum. With each com-plete operation of the algorithm, the edges in the patternare reduced by a factor of τ. The pattern of a Penrosetiling begins to emerge as we proceed and all the knowndistinct vertices appear when the length scale reachesa/(τ6). Such a complete Penrose tiling shown in Figure1 d, is obtained after reflecting the structure derived atn = 7 in a mirror placed along AC. The ratio of the edgelength of a tile (an) to the edge of the rhomb tiled (a) willalways be τ n, where n represents the number of times thescale length has been reduced by a factor of τ. All furtherdiscussions refer to the tiling within this rhomb. Manyothers have repeatedly stressed the self-similar nature ofthe Penrose tiling. The present algorithm is the first toemploy an iterative procedure commonly employed togenerate deterministic fractals. This novel algorithmwhich has an initiator (lines at 108° to each other), agenerator (erection of isosceles triangles with sides 1/τtimes the previous length scale and erasing all sides ofother length scales) and cascading is typical of pro-cedures which generate patterns with fractal dimensions.This procedure also obviates the need for assembling tilesaccording to matching rules of Penrose. In addition, itpermits us to utilize various procedures developed fordetermining the fractal dimension of patterns arising fromsuch an algorithm.  Conventionally, the estimation of the fractal dimensionof a non-random fractal based on an iterative scheme ofthe above three steps is given as,,)/1log()log(lt0f lNDl→=where N is the number of edges of length l which occurwithin the fractal object. The discovery of quasi-crystalshas conclusively demonstrated that aperiodic packing ofatoms occurs in nature. In a Penrose tiling, the closestdistance of separation of two atoms can only be along theshort diagonal of a thin rhomb. For the present algorithm,if the edge length of a rhomb is taken as the reference,when n tends to infinity, the edge length tends to zero andthe rhomb collapses to a point. Thus it would not be app-ropriate to evaluate the fractal dimension of the tiling inthe limit when n tends to infinity. Therefore, when oneconsiders the Penrose tiling from a crystallographic pointof view, a limit has to be placed on the value of n, thenumber of recursions of the algorithm. The recursionshave to be limited only to the extent of achieving dis-tances of separation of the order of atomic spacingsbetween the vertices in the tiling. From the point of viewof the present algorithm, one achieves atomic distances ofseparation from a starting separation, a, of 1 cm in 39recursions. Hence, the formula for Df can be modified as,,)log()log(lt 1f −′→=nnnNDτwhere n′ is the physical limit on the number of recursions.One can obtain the edge length and the number of verticesgenerated in a tiling in terms of the Fibonacci numbers.These have been estimated as:Nvertices = F2n +1 + 4Fn,,282 verticesedges nnAFNN +−=  where F represents the respective Fibonacci numbers in asequence starting with zero. An is an even integer depen-dent on n. Based on an analysis using the edge length inthe above formula for Df , we arrive at a value of theHausdorff dimension as 1.974 using the size of n′ as 39.This value is close to the fractal dimension obtainedfor the growth of two-dimensional clusters of atoms.However, it may be noted that limit of Df as n → ∞ existsand its value is 2, implying a non-fractal space fillingstructure.  Quasicrystals which incorporate aperiodic tilings, likePenrose tiling, are known to grow by the clustering pro-cess. Recently Lord et al.5 have shown that the clusteringprocess is very similar to the way quasicrystals actuallygrow. A cluster is conceived to grow by accretion of suc-cessive shells around an initial seed, such as a 12- or 13-5RESEARCH COMMUNICATIONSCURRENT SCIENCE, VOL. 79, NO. 3, 10 AUGUST 2000366atom icosahedron. The clusters grow as they bond to eachother by sharing the atoms. One of the most commonlydiscussed cluster growth models is the diffusion-limitedaggregation (DLA) of atoms8–10. DLA exhibits randombranching during growth and can be shown as a non-deterministic fractal, governed by the sticking probability.Notwithstanding this randomness, DLA manifests, irres-pective of the magnitude of the sticking probability, someimportant regularities in an average sense10, e.g. (i) themost probable value of the angle between neighbouringbranches is found to be 36°, and (ii) Fibonacci numbersare known to occur in DLA clusters. In Penrose tilingsalso, these two parameters, viz. the angle of 36° and Fibo-nacci numbers, govern the pattern generation. Howeverunlike those in DLA, the angles in a tiling are exact multi-ples of 36° and the number of tiles, edges and vertices areprecise functions of the Fibonacci numbers as shownabove. It remains to be seen as to how a deterministicalgorithm for Penrose tiling, like the one generated in thepresent study, and diffusion controlled probabilistic DLAalgorithm of Whitten and Sander9 bear these importantsimilarities. 1. Penrose,  R., Bull. Inst. Math. Appl., 1974, 10, 266–271. 2. Gardner, M., Sci. Am., January 1977, 110–121. 3. Stewart, I., Sci. Am., July 1999, 96–98. 4. Mackay, A. L., Physica A, 1982, 114, 609. 5. Lord, E. A., Ranganathan, S. and Kulkarni, U. D., Curr. Sci.,2000, 78, 64–72. 6. Mandelbrot, B. B., Fractal Geometry of Nature, W.H. Freeman,San Francisco, 1983. 7. Penrose, R., Aperiodicity and Order (ed. Jaric, M. V.), 1989,vol. 2, pp. 69–110. 8. Kaye, B., Chaos and Complexity, VCH, New York, 1993. 9. Whitten, T. A. and Sander, L. M., Phys. Rev. Lett., 1981, 47,1400–1403. 10. Stewart, I., New Sci., August 1992, 14.ACKNOWLEDGEMENTS.  We are grateful to Professors N. Kumar,S. Ranganathan, G. Ananthakrishna, Shrikant Lele, G. V. S. Sastry andDr R. K. Mandal for helpful discussions.Received 21 February 2000; revised accepted 1 June 2000Participatory approach in varietalimprovement: A case study in fingermillet in IndiaB. T. S. Gowda*, B. H. Halaswamy*, A. Seetharam*,D. S. Virk† and J. R. Witcombe†*Project Coordination Cell, AICRP on Small Millets, GKVK,Bangalore 560 065,India†Centre for Arid Zone Studies, University of Wales,Bangor LL 57 2UW, UKCrop improvement research has made a significantcontribution in the last 5 decades through the deve-lopment and release of a large number of varieties inall important crops for general cultivation. It is gener-ally felt that the modern plant breeding has cateredmore to the needs of rich farmers who could affordhigh management under irrigated situations. In con-trast, subsistence farmers growing millets and otherminor crops in unfavourable environments use lowlevels of inputs and have not been benefitted by highyielding variety (HYV) technology. In the presentcase study, the usefulness of the participatory app-roach for identifying cultivars for harsh environmentsand acceptable to resource-poor farmers has beendemonstrated. The study carried out in Chitradurgadistrict using six finger millet varieties with 150 farmerspointed out the effectiveness of such an approach inidentifying cultivars for meeting the requirement ofthe resource-poor farmers under real farm situations.Another important outcome of the farmer participa-tory varietal trial has been the identification of a mostsuitable variety for growing in a specific niche as asecond crop which otherwise would have been diffi-cult under the variety evaluation system confining toresearch stations.CROP improvement research has been in progress sincethe beginning of this century. However, progress in plantbreeding has been phenomenal in the last 5 decades inIndia. The coordinated crop improvement programme wasfirst conceived in maize during 1956 and later on ex-panded to all the other important crops either individuallyor in groups under the National Agricultural ResearchSystem (NARS). The conceptualization of land grant sys-tem of agricultural research, education and extension andthe establishment of agricultural universities further helpedin developing broad-based agricultural research activitiesto address the agricultural research needs of differentstates. As a result, a large number of varieties were bredand released for general cultivation in all important cropsin the country. The successful adoption of these varietiesalong with improved cultivation practices helped in a 4-fold increase in food grain production, from 50 milliontonnes to more than 200 million tonnes. However, much*For correspondence. (e-mail: btsg@uasblr.kar.nic.in)author

On the fractal nature of Penrose tiling

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On the fractal nature of Penrose tiling

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