Let n in N. For A\subseteq N, | A| = n the minimum of |S_A| is obtained by arithmetic progressions A and the maximum by Sidon sets A. Therefore one can expect that a well-covering of a Sidon set by arithmetic progressions is impossible, even by generalized arithmetic progressions P = {e+x₁ f₁+···+x_m f_m | x_i in {1, ..., l_i} for i = 1,..., m}, where m,l₁, ..., l_m in N; e,f₁, ..., f_m in Z. Let dim P = m and Q(P) = l₁ l₂ ... l_m be the dimension and size of P. A measure of well-covering for A by generalized arithmetic progressions (g.a.p.) of dimension m is given by the minimum D_m (A) of the terms tsum^t_{j = 1} Q(P_j) taken over all coverings A\subseteq \bigcup^t_{j = 1} P_j where P_j are g.a.p. with dim P_j = m for j = 1, ..., t. If D_m (A) is close to |A| then A can be covered by ``few'' g.a.p.. If D_m (a) is close to |A|² we have the opposite situation. For all finite Sidon sets A it is shown that D_m(A) > 2^-m-1 |A|². On the other hand for all m in N there exists a finite Sidon set A such that D_m(A) \leq ¹/₂ | A|². These two theorems are proved in a more general form for B₂[g] sets.
Reviewer:  J.Zöllner (Mainz)
Classif.:  * 11B13 Additive bases
                   11B25 Arithmetic progressions
Keywords:  sum sets of Sidon sets; additive bases; B₂-sequences; B₂[g] sets; arithmetic progressions

© European Mathematical Society & FIZ Karlsruhe & Springer-Verlag

Books	Problems	Set Theory	Combinatorics	Extremal Probl/Ramsey Th.
Graph Theory	Add.Number Theory	Mult.Number Theory	Analysis	Geometry
Probabability	Personalia	About Paul Erdös	Publication Year	Home Page