On the complexity of computing Kostka numbers and Littlewood-Richardson coefficients
Hariharan Narayanan
University of Chicago Department of Computer Science Chicago USA Chicago USA
DOI: 10.1007/s10801-006-0008-5
Abstract
Kostka numbers and Littlewood-Richardson coefficients appear in combinatorics and representation theory. Interest in their computation stems from the fact that they are present in quantum mechanical computations since Wigner [15]. In recent times, there have been a number of algorithms proposed to perform this task [1-3, 11, 12]. The issue of their computational complexity has received at-tention in the past, and was raised recently by E. Rassart in [11]. We prove that the problem of computing either quantity is # P-complete. Thus, unless P = NP, which is widely disbelieved, there do not exist efficient algorithms that compute these numbers.
Pages: 347–354
Keywords: keywords Kostka numbers; Littlewood-Richardson coefficients; computational complexity
Full Text: PDF
References
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2. S. Billey, V. Guillemin, and E. Rassart, “A vector partition function for the multiplicities of slk (C),” Journal of Algebra 278(1) (2004), 251-293.
3. C. Cochet, Kostka Numbers and Littlewood-Richardson Coefficients, preprint (2003).
4. M. Dyer, R. Kannan, and J. Mount, Sampling contingency tables, Random Structures and Algorithms 10 (1997), 487-506.
5. W. Fulton, “Young Tableaux,” London Mathematical Society Student Texts 35 (1997).
6. D. E. Knuth, “Permutations, matrices, and generalized Young tableaux,” Pacific Journal of Mathematics 34 (1970), 709-727.
7. A. Knutson and T. Tao, “The honeycomb model of tensor products I: Proof of the saturation conjecture,” J. Amer. Math. Soc. 12 (1999), 1055-1090.
8. K. Mulmuley and M, Sohoni, “Geometric Complexity III: on deciding positivity of Littlewood- Richardson coefficients,” http://arxiv.org/abs/cs.CC/0501076
9. K. Mulmuley and M. Sohoni, “Geometric complexity theory, P vs. NP, and explicit obstructions.,” in Proceedings, International Conference on Algebra and Geometry, Hyderabad (2001).
10. I. Pak and E. Vallejo, “Combinatorics and geometry of Littlewood-Richardson cones,” Europ. J. Combinatorics 26 (2005), 995-1008.
11. E. Rassart, “Geometric approaches to computing Kostka numbers and Littlewood-Richardson coefficients,” Thesis for the Ph.D. degree in Mathematics, Massachusetts Institute of Technology (MIT), 2004.
12. E. Rassart, “A polynomiality property for Littlewood-Richardson coefficients,” Journal of Combinatorial Theory, Series A 107(2) (2004), 161-179.
13. L.G. Valiant, “The complexity of computing the permanent,” Theoret. Comp. Sci. 8 (1979), 189-201.
14. M.A.A. van Leeuwen, “The Littlewood-Richardson rule, and related combinatorics,” Math. Soc. of Japan Memoirs 11, Interaction of Combinatorics and Representation Theory; arXiv:math.CO/9908099.
15. E. Wigner, “On the consequences of the symmetry of the nuclear Hamiltonian on the spectroscopy of the nuclei,” Physical Review 51 (1937), 106-119.