Abstract
The area of a spherical region can be easily measured by considering which sampling points of a lattice are located inside or outside the region. This point-counting technique is frequently used for measuring the Earth coverage of satellite constellations, employing a latitude–longitude lattice. This paper analyzes the numerical errors of such measurements, and shows that they could be greatly reduced if the Fibonacci lattice were used instead. The latter is a mathematical idealization of natural patterns with optimal packing, where the area represented by each point is almost identical. Using the Fibonacci lattice would reduce the root mean squared error by at least 40%. If, as is commonly the case, around a million lattice points are used, the maximum error would be an order of magnitude smaller.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adler I, Barabe D, Jean RV (1997) A history of the study of phyllotaxis. Ann Bot 80(3):231–244
Ahmad R, Deng Y, Vikram DS, Clymer B, Srinivasan P, Zweier JL, Kuppusamy P (2007) Quasi Monte Carlo-based isotropic distribution of gradient directions for improved reconstruction quality of 3D EPR imaging. J Magn Reson 184(2):236–245
Baddeley A, Jensen EBV (2004) Stereology for statisticians. Chapman and Hall–CRC Press, Boca Raton
Barclay M, Galton A (2008) Comparison of region approximation techniques based on Delaunay triangulations and Voronoi diagrams. Comput Environ Urban Syst 32(4):261–267
Bardsley WE (1983) Random error in point counting. Math Geol 15(3):469–475
Bauer R (2000) Distribution of points on a sphere with application to star catalogs. J Guid Control Dyn 23(1):130–137
Bevington PR, Robinson DK (1992) Data reduction and error analysis for the physical sciences, 2nd edn. McGraw Hill, Boston
Bevis M, Cambareri G (1987) Computing the area of a spherical polygon of arbitrary shape. Math Geol 19(4):335–346
Brauchart JS (2004) Invariance principles for energy functionals on spheres. Monatsh Math 141(2):101–117
Bravais L, Bravais A (1837) Essai sur la disposition des feuilles curvisériées. Ann Sci Nat 7:42–110, plates 2–3
Chukkapalli G, Karpik SR, Ethier CR (1999) A scheme for generating unstructured grids on spheres with application to parallel computation. J Comput Phys 149(1):114–127
Conway JH, Sloane NJA (1998) Sphere packings, lattices and groups, 3rd edn. Springer, New York
Cui J, Freeden W (1997) Equidistribution on the sphere. SIAM J Sci Comput 18(2):595–609
Damelin SB, Grabner PJ (2003) Energy functionals, numerical integration and asymptotic equidistribution on the sphere. J Complex 19(3):231–246 [Corrigendum 20(6):883–884]
Dixon R (1987) Mathographics. Basil Blackwell, Oxford
Dixon R (1989) Spiral phyllotaxis. Comput Math Appl 17(4–6):535–538
Dixon R (1992) Green spirals. In: Hargittai I, Pickover CA (eds) Spiral symmetry. World Scientific, Singapore, pp 353–368
Douady S, Couder Y (1992) Phyllotaxis as a physical self-organized growth process. Phys Rev Lett 68(13):2098–2101
Earle MA (2006) Sphere to spheroid comparisons. J Navig 59(3):491–496
Erikson RO (1973) Tubular packing of spheres in biological fine structure. Science 181(4101):705–716
Evans DG, Jones SM (1987) Detecting Voronoi (area-of-influence) polygons. Math Geol 19(6):523–537
Feng S, Ochieng WY, Mautz R (2006) An area computation based method for RAIM holes assessment. J Glob Position Syst 5(1–2):11–16
Fowler DR, Prusinkiewicz P, Battjes J (1992) A collision-based model of spiral phyllotaxis. ACM SIGGRAPH Comput Graph 26(2):361–368
González Á (2009) Self-sharpening seismicity maps for forecasting earthquake locations. Abstracts of the sixth international workshop on statistical seismology. Tahoe City, California, 16–19 April 2009. http://www.scec.org/statsei6/posters.html
Gregory MJ, Kimerling AJ, White D, Sahr K (2008) A comparison of intercell metrics on discrete global grid systems. Comput Environ Urban Syst 32(3):188–203
Greiner B (1999) Euler rotations in plate-tectonic reconstructions. Comput Geosci 25(3):209–216
Gundersen HJG, Jensen EBV, Kiêu K, Nielsen J (1999) The efficiency of systematic sampling in stereology—reconsidered. J Microsc 193(3):199–211
Hannay JH, Nye JF (2004) Fibonacci numerical integration on a sphere. J Phys A 37(48):11591–11601
Howarth RJ (1998) Improved estimators of uncertainty in proportions, point-counting, and pass-fail test results. Am J Sci 298(7):594–607
Hüttig C, Stemmer K (2008) The spiral grid: A new approach to discretize the sphere and its application to mantle convection. Geochem Geophys Geosyst 9(2):Q02018
Huxley MN (1987) The area within a curve. Proc Indian Acad Sci, Math Sci 97(1–3):111–116
Huxley MN (2003) Exponential sums and lattice points III. Proc Lond Math Soc 87(3):591–609
Jarái A, Kozák M, Rózsa P (1997) Comparison of the methods of rock-microscopic grain-size determination and quantitative analysis. Math Geol 29(8):977–991
Jean RV (1994) Phyllotaxis: a systemic study of plant pattern morphogenesis. Cambridge University Press, Cambridge
Kafka AL (2007) Does seismicity delineate zones where future large earthquakes are likely to occur in intraplate environments? In: Stein S, Mazzotti S (eds) Continental intraplate earthquakes: science, hazard, and policy issues. Geological Society of America special paper 425, Boulder, Colorado, pp 35–48
Kantsiper B, Weiss S (1998) An analytic approach to calculating Earth coverage. Adv Astronaut Sci 97:313–332
Kendall DG (1948) On the number of lattice points inside a random oval. Quart J Math Oxford 19(1):1–26
Kimerling AJ (1984) Area computation from geodetic coordinates on the spheroid. Surv Mapp 44(4):343–351
Klíma K, Pick M, Pros Z (1981) On the problem of equal area block on a sphere. Stud Geophys Geod (Praha) 25(1):24–35
Knuth DE (1997) Art of computer programming, 3rd edn. Fundamental algorithms, vol 1. Addison-Wesley, Reading
Kossobokov V, Shebalin P (2003) Earthquake prediction. In: Keilis-Borok VI, Soloviev AA (eds) Nonlinear dynamics of the lithosphere and earthquake prediction. Springer, Berlin, pp 141–207. [References in pp 311–332]
Kozin MB, Volkov VV, Svergun DI (1997) ASSA, a program for three-dimensional rendering in solution scattering from biopolymers. J Appl Cryst 30(5):811–815
Kuhlemeier C (2007) Phyllotaxis. Trends Plant Sci 12(4):143–150
Lean JL, Picone JM, Emmert JT, Moore G (2006) Thermospheric densities derived from spacecraft orbits: application to the Starshine satellites. J Geophys Res 111(4):A04301
Li C, Zhang X, Cao Z (2005) Triangular and Fibonacci number patterns driven by stress on core/shell microstructures. Science 309(5736):909–911
Maciá E (2006) The role of aperiodic order in science and technology. Rep Prog Phys 69(2):397–441
Maley PD, Moore RG, King DJ (2002) Starshine: A student-tracked atmospheric research satellite. Acta Astronaut 51(10):715–721
Michalakes JG, Purser RJ, Swinbank R (1999) Data structure and parallel decomposition considerations on a Fibonacci grid. In: Preprints of the 13th conference on numerical weather prediction, Denver, 13–17 September 1999. American Meteorological Society, pp 129–130
Na HS, Lee CN, Cheong O (2002) Voronoi diagrams on the sphere. Comput Geom Theory Appl 23(2):183–194
Niederreiter H (1992) Random number generation and quasi-Monte Carlo methods. Society for Industrial and Applied Mathematics, Philadelphia
Niederreiter H, Sloan IH (1994) Integration of nonperiodic functions of two variables by Fibonacci lattice rules. J Comput Appl Math 51(1):57–70
Nye JF (2003) A simple method of spherical near-field scanning to measure the far fields of antennas or passive scatterers. IEEE Trans Antenna Propag 51(8):2091–2098
Ochieng WY, Sheridan KF, Sauer K, Han X (2002) An assessment of the RAIM performance of a combined Galileo/GPS navigation system using the marginally detectable errors (MDE) algorithm. GPS Solut 5(3):42–51
Prusinkiewicz P, Lindenmayer A (1990) The algorithmic beauty of plants. Springer, New York
Purser RJ (2008) Generalized Fibonacci grids: A new class of structured, smoothly adaptive multi-dimensional computational lattices. Office Note 455, National Centers for Environmental Prediction, Camp Springs, MD, USA
Purser RJ, Swinbank R (2006) Generalized Euler-Maclaurin formulae and end corrections for accurate quadrature on Fibonacci grids. Office Note 448, National Centers for Environmental Prediction, Camp Springs, MD, USA
Rakhmanov EA, Saff EB, Zhou YM (1994) Minimal discrete energy on the sphere. Math Res Lett 1(6):647–662
Ridley JN (1982) Packing efficiency in sunflower heads. Math Biosci 58(1):129–139
Ridley JN (1986) Ideal phyllotaxis on general surfaces of revolution. Math Biosci 79(1):1–24
Saff EB, Kuijlaars ABJ (1997) Distributing many points on a sphere. Math Intell 19(1):5–11
Sigler LE (2002) Fibonacci’s Liber Abaci: a translation into modern English of Leonardo Pisano’s book of calculation. Springer, New York
Singh P (1985) The so-called Fibonacci numbers in ancient and medieval India. Hist Math 12(3):229–244
Sjöberg LE (2006) Determination of areas on the plane, sphere and ellipsoid. Surv Rev 38(301):583–593
Sloan IH, Joe S (1994) Lattice methods for multiple integration. Oxford University Press, London
Svergun DI (1994) Solution scattering from biopolymers: advanced contrast-variation data analysis. Acta Cryst A 50(3):391–402
Swinbank R, Purser RJ (1999) Fibonacci grids. In: Preprints of the 13th conference on numerical weather prediction, Denver, 13–17 September 1999. American Meteorological Society, pp 125–128
Swinbank R, Purser RJ (2006a) Standard test results for a shallow water equation model on the Fibonacci grid. Forecasting Research Technical Report 480, Met Office, Exeter, UK
Swinbank R, Purser RJ (2006b) Fibonacci grids: a novel approach to global modelling. Q J R Meteorol Soc 132(619):1769–1793
Van den Dool HM (2007) Empirical methods in short-term climate prediction. Oxford University Press, London
Vogel H (1979) A better way to construct the sunflower head. Math Biosci 44(3–4):179–189
Vriend G (1990) WHAT IF: a molecular modeling and drug design program. J Mol Graph 8(1):52–56
Weiller AR (1966) Probleme de l’implantation d’une grille sur une sphere, deuxième partie. Bull Géod 80(1):99–111
Weisstein EW (2002) CRC concise encyclopedia of mathematics CD-ROM, 2nd edn. CRC Press, Boca Raton
Wessel P, Smith WHF (1998) New, improved version of Generic Mapping Tools released. Eos Trans Am Geophys Union 79(47):579
Williamson DL (2007) The evolution of dynamical cores for global atmospheric models. J Meteorol Soc Jpn B 85:241–269
Winfield DC, Harris KM (2001) Phyllotaxis-based dimple patterns. Patent number WO 01/26749 Al. World Intellectual Property Organization
Zaremba SK (1966) Good lattice points, discrepancy, and numerical integration. Ann Mat Pura Appl 73(1):293–317
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
González, Á. Measurement of Areas on a Sphere Using Fibonacci and Latitude–Longitude Lattices. Math Geosci 42, 49–64 (2010). https://doi.org/10.1007/s11004-009-9257-x
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11004-009-9257-x