Abstract
Bent and almost-bent functions on \({\mathbb{Z}_p^2}\) are studied in this paper. By calculating certain exponential sum and using a technique due to Hou (Finite Fields Appl 10:566–582, 2004), we obtain a degree bound for quasi-bent functions, and prove that almost-bent functions on \({\mathbb{Z}_p^2}\) are equivalent to a degenerate quadratic form. From the viewpoint of relative difference sets, we also characterize bent functions on \({\mathbb{Z}_p^2}\) in two classes of \({\mathcal{M}}\) ’s and \({\mathcal{PS}}\) ’s, and show that the graph set corresponding to a bent function on \({\mathbb{Z}_p^2}\) can be written as the sum of a graph set of \({\mathcal{M}}\) ’s type bent function and another group ring element. By using our characterization and some technique of permutation polynomial, we obtain the result: a bent function must be of \({\mathcal{M}}\) ’s type if its corresponding set contains more than (p − 3)/2 flats. A problem proposed by Ma and Pott (J Algebra 175:505–525, 1995) is therefore partially answered.
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Zhang, X., Guo, H. & Gao, Z. Characterizations of Bent and Almost Bent Function on \({\mathbb{Z}_p^2}\) . Graphs and Combinatorics 27, 603–620 (2011). https://doi.org/10.1007/s00373-010-0980-3
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DOI: https://doi.org/10.1007/s00373-010-0980-3