Maass Waveforms on (Γ<span class='sub'>0</span>(<span class='italic'>N</span>), χ) (Computational Aspects)

doi:10.1017/CBO9781139108782.007

VI - Maass Waveforms on (Γ0(N), χ) (Computational Aspects)

Published online by Cambridge University Press: 05 January 2012

Fredrik Strömberg

Edited by

Jens Bolte and

Frank Steiner

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Fredrik Strömberg: Affiliation:
TU Darmstadt, Germany
Jens Bolte: Affiliation:
Royal Holloway, University of London
Frank Steiner: Affiliation:
Universität Ulm, Germany

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Summary. The main topic of this paper is computational aspects of the theory of Maass waveforms, i.e. square-integrable eigenfunctions of the Laplace-Beltrami operator on certain Riemann surfaces with constant negative curvature and finite area. The surfaces under consideration correspond to quotients of the upper half-plane by certain discrete groups of isometries, the so called Hecke congruence subgroups.

It is known that such functions can also be regarded as wavefunctions corresponding to a quantum-mechanical system describing a particle moving freely on the surface. Since the classical counterpart of this motion is chaotic, the study of these wavefunctions is closely related to the study of quantum chaos on the surface. The presentation here, however, will be purely from a mathematical viewpoint.

Today, our best knowledge of generic Maass waveforms comes from numerical experiments, and these have previously been limited to the modular group, PSL(2, ℤ), and certain triangle groups (cf. [13, 14, 16] and [39]). One of the primary goals of this lecture is to give the necessary theoretical background to generalize these numerical experiments to Hecke congruence subgroups and non-trivial characters. We will describe algorithms that can be used to locate eigenvalues and eigenfunctions, and we will also present some of the results obtained by those algorithms.

There are four parts, first elementary notations and definitions, mostly from the study of Fuchsian groups and hyperbolic geometry. Then more of the theoretical background needed to understand the rich structure of the space of Maass waveforms will be introduced. The third chapter deals with the computational aspects, and the final chapter contains some numerical results.

Type: Chapter
Information: Hyperbolic Geometry and Applications in Quantum Chaos and Cosmology , pp. 187 - 228

DOI: https://doi.org/10.1017/CBO9781139108782.007 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

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References

1. A. O. L., Atkin and J., Lehner, Hecke operators on Γ0(M), Math. Ann. 185 (1970), 134-160.Google Scholar

2. A. O. L., Atkin and W.-C. W., Li, Twists of newforms and pseudo-eigenvalues of W-operators, Invent. Math. 48 (1978), no. 3, 221–243.Google Scholar

3. R., Aurich, F., Steiner, and H., Then, Numerical computation of Maass waveforms and an application to cosmology, this volume.

4. H., Avelin, On the Deformation of Cusp Forms, 2003, Filosofie Licentiat avhandling.Google Scholar

5. E., Balslev and A., Venkov, Spectral theory of Laplacians for Hecke goups with primitive character, Acta Math. 186 (2001), 155–217.Google Scholar

6. A., Booker, A., Strömbergsson, and A., Venkatesh, Effective Computation of Cusp Forms, Int. Math. Res. Not. (2006), Art. ID 71281, 34 pp.Google Scholar

7. D., Bump, Automorphic Forms and Representations, Cambridge Studies in Advanced Mathematics, no. 55, Cambridge University Press, 1996.Google Scholar

8. H., Cohn, Advanced Number Theory, Dover, 1980.Google Scholar

9. D., Davenport, Multiplicative Number Theory, 2 ed., Graduate Texts in Mathematics, no. 74, Springer-Verlag, 1980.Google Scholar

10. L. R., Ford, Automorphic Functions, 2nd ed., Chelsea Publishing, 1972.Google Scholar

11. E., Hecke, Mathematische Werke, Vandhoeck & Ruprecht, Göttingen, 1970.Google Scholar

12. D. A., Hejhal, The Selberg Trace Formula for PSL(2,ℕ), vol.2, Lecture Notes in Mathematics, vol. 1001, Springer-Verlag, Berlin, 1983.Google Scholar

13. D. A., Hejhal, Eigenvalues of the Laplacian for Hecke triangle groups, Mem. Amer. Math. Soc. 97 (1992), no. 469, vi+165.Google Scholar

14. D. A., Hejhal, On eigenfunctions of the Laplacian for Hecke triangle groups, Emerging applications of number theory (ed. by D., Hejhal and J., Friedman et al), IMA Vol. Math. Appl., vol. 109, Springer, New York, 1999, pp. 291–315.Google Scholar

15. D. A., Hejhal, On the Calculation of Maass Cusp Forms, these proceedings.

16. D. A., Hejhal and S., Arno, On Fourier coefficients of Maass waveforms for PSL(2, ℤ), Math. Comp. 61 (1993), no. 203, 245–267, S11–S16.Google Scholar

17. D. A., Hejhal and A., Strömbergsson, On quantum chaos and Maass waveforms of CM-type, Foundations of Physics 31 (2001), 519–533.Google Scholar

18. M. N., Huxley, Scattering matrices for congruence subgroups, in Modular forms (ed. by R., Rankin), Ellis Horwood, Chichester, 1984, pp. 141–156.Google Scholar

19. H., Iwaniec, Introduction to the Spectral Theory of Automorphic Forms, Revista Matemática Iberoamericana, 1995.Google Scholar

20. H., Iwaniec, Topics in Classical Automorphic Forms, AMS, 1997.Google Scholar

21. S., Katok, Fuchsian Groups, The University of Chicago Press, 1992.Google Scholar

22. S. L., Krushkal, B. N., Apanasov, and N. A., Gusevskii, Kleinian Groups and Uniformization in Examples and Problems, Translations of Mathematical Monographs, AMS, 1986.Google Scholar

23. H., Maass, Über eine neue Art von nichtanalytischen automorphen Funktionen und die Bestimmung Dirichletscher Reihen durch Funktionalgleichungen, Math. Annalen 121 (1949), 141–183.Google Scholar

24. H., Maass, Lectures on Modular Munctions of One Complex Variable, second ed., Tata Institute of Fundamental Research Lectures on Mathematics and Physics, vol. 29, Tata Institute of Fundamental Research, Bombay, 1983.Google Scholar

25. B., Maskit, Kleinian Groups, Springer-Verlag, 1988.Google Scholar

26. T., Miyake, On automorphic forms on GL2 and Hecke operators, Ann. of Math. (2) 94 (1971), 174–189.Google Scholar

27. T., Miyake, Modular Forms, Springer-Verlag, 1997.Google Scholar

28. A., Orihara, On the Eisenstein series for the principal congruence subgroups, Nagoya Math. J. 34 (1969), 129–142.Google Scholar

29. R. S., Phillips and P., Sarnak, On cusp forms for co-finite subgroups of PSL(2,ℝ), Invent. Math. 80 (1985), 339–364.Google Scholar

30. H., Rademacher, Über die Erzeugenden von Kongruenzuntergruppe der Modulgruppe, Abhandlungen Hamburg 7 (1929), 134–148.Google Scholar

31. R. A., Rankin, Modular Forms and Functions, Cambridge University Press, 1976.Google Scholar

32. J. G., Ratcliffe, Foundations of Hyperbolic Manifolds, Springer-Verlag, 1994.Google Scholar

33. M. S., Risager, A symptotic densities of Maass newforms, J. Number Theory 109 (2004), no. 1, 96–119.Google Scholar

34. B., Selander, Arithmetic of three-point covers, PhD thesis, Uppsala University, 2001, http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-7497.

35. G., Shimura, Introduction to the Arithmetic Theory of Automorphic Forms, Princeton Univ Press, 1971.Google Scholar

36. A., Strömbergsson, Studies in the analytical and spectral theory of automorphic forms, Ph.D. thesis, Uppsala University, Dept. of Math., 2001.

37. F., Strömberg, Computational aspects of Maass waveforms, Ph.D. thesis, Uppsala University, Dept. of Math., 2005.

38. A., Terras, Harmonic Analysis on Symmetric Spaces and Applications, vol. I, Springer-Verlag, New York, 1985.Google Scholar

39. H., Then, Maass cusp forms for large eigenvalues, Math. Comp. 74 (2005), no. 249, 363–381.Google Scholar

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VI - Maass Waveforms on (Γ0(N), χ) (Computational Aspects)

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