This article investigates the superdirectivity limits of end-fire linear arrays based on closely spaced radiating elements. First, directivity upper bounds have been derived analytically in the case of Huygens-source- and electrical-dipole-based arrays using spherical wave expansion (SWE). The fundamental bounds are derived when the interelement spacing $d$ tends to 0 and as a function of the number of the elements ( $P$ ) composing the array. Furthermore, the complex excitation coefficients associated with end-fire arrays of $P$ infinitesimal Huygens sources and electrical dipoles are synthesized as a function of $d$ to achieve maximum directivity. For this purpose, synthesis procedures based on SWE and array theory are used. When $d$ tends to 0, the numerical results are in excellent agreement with the proposed upper bounds. The maximum superdirectivity approaches a value of P $^{2}+$ 2 $P$ and $P^{2} + P - 1/2$ , respectively, in the case of Huygens sources and electrical dipoles. A numerical method to estimate the antenna gain, when the arrays are optimized in terms of directivity, is also provided. The theoretical results are then successfully validated through electromagnetic simulations in the case of half-wavelength-dipole-based arrays as a function of $P$ and $d$ . Three prototypes are designed and experimentally characterized as well to demonstrate the proposed analysis.