Receiving mutual impedance between two printed dipole antennas

## Abstract We present a new circuit‐model approach which can be used to compute the mutual impedance between two dipoles fed at the same feed point. The validity of the method is confirmed by comparison with mutual impedance values obtained when the dipoles are individually excited and orientated

## Abstract A formula for mutual impedance between patch antennas is constructed based on the physics of the static near field and the radiation far field of the couplings. This leads to a __synthetic asymptote__ form [1] of separated variables of the center‐to‐center distance __r__ and the azimuth

## Abstract Printed antennas are very popular for commercial and military RF (radio frequency)/microwave communication systems because there is an enormous evolution in printed circuit technology. In this study, printed monopole and filamentary excited dipole, which are basic models and easily appl

## Abstract A planar wideband multi‐input multi‐output (MIMO) antenna for small mobile devices is introduced. The proposed MIMO antenna system made up with two identical antennas operates in 2.3–5.9 GHz, which corresponds to Wibro 802.11a, 802.11b and Mobile WiMax 802.11n bands. The enhanced perfor

## Abstract A formula for mutual impedance between patch antennas is constructed, based on the physics of the static near field and the radiation far field of the couplings. This leads to a synthetic asymptote form [1] of separated variables with center‐to‐center distance __r__ and azimuth angle ϕ.

The analysis of mutual coupling between two circular patch antennas integrated in an inhomogeneous substrate ¨ia a com-( ) ( ) bined spectral domain SD and method of moments MoM is proposed in this paper. The spectral electromagnetic field inside the inhomogeneous grounded slab is expressed ¨ia the