Unifying the Theory of Mutual Coupling Compensation in Antenna Arrays

Henault, S.; Antar, Yahia M. M.

doi:10.1109/map.2015.2414514

Cited by 39 publications

(27 citation statements)

References 86 publications

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“…The impedance matrix model can work in special cases but is generally incorrect (Henault & Antar, ), since this analysis is limited to the circuit level. Full radiation pattern measurements or calculations are required in general.…”

Section: Conventional Null Steeringmentioning

confidence: 99%

Investigation of a 256‐Monopole Transmit Antenna Array for Over‐the‐Horizon Radar in Canada

Henault

Riddolls

2019

Radio Science

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A 256‐monopole planar array is investigated as a potential transmit antenna covering the entire 3‐ to 18‐MHz band in an over‐the‐horizon radar (OTHR) operating at high latitudes in Canada. This array is relatively inexpensive, simple to build, and offers the azimuth and elevation resolutions necessary to defeat the auroral clutter which has traditionally limited the operation of OTHR at high latitudes. It is demonstrated that excellent clutter rejection ratios are possible with this antenna array and accurate calibration, but significant performance degradation occurs with calibration errors in particular in the lower portion of the operating frequency band. Various calibration approaches and error mechanisms are studied. A new approach combining multiple‐input‐multiple‐output (MIMO) radar techniques at lower frequencies and conventional transmit null steering at higher frequencies is proposed and evaluated. This approach enhances the robustness of the array to calibration errors while preserving the radar unambiguous range‐Doppler space across the operating frequency band.

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Section: Conventional Null Steeringmentioning

confidence: 99%

Investigation of a 256‐Monopole Transmit Antenna Array for Over‐the‐Horizon Radar in Canada

Henault

Riddolls

2019

Radio Science

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“…To explain it more intuitively and provide a reliable foundation for the proposed scheme, we provide the S-parameter characteristics of two kinds of arrays below as an example. In practical applications, S-parameters are typically used to characterize the mutual coupling and , p q S captures the coupling degree between the p-th element and the q-th element [42]. Figure 2 exhibits the S-parameter characteristics from an electromagnetic simulation software, i.e., HFSS, where two ten-element ULAs composed of microstrip antennas and dipole antennas are studied.…”

Section: Data Model With Mutual Couplingmentioning

confidence: 99%

An Array Switching Strategy for Direction of Arrival Estimation with Coprime Linear Array in the Presence of Mutual Coupling

Shen

2020

Sensors

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While the coprime array still suffers from performance degradation due to the mutual coupling dominated by the interleaved subarrays, we propose an array switching strategy for coprime linear array (CLA) by utilizing the large inter-element spacings of the subarrays to mitigate the mutual coupling. Specifically, we first collect the signals by separately activating the two subarrays, where the severe mutual coupling effect is significantly reduced. As a result, well-performed initial direction of arrival (DOA) estimates can be achieved. Subsequently, we establish a quadratic optimization problem by reconstructing the contaminated steering vector of the total CLA elaborately to calculate the mutual coupling coefficients with the initial DOA estimates. Finally, we can obtain refined DOA estimates by an iteration procedure based on the estimated mutual coupling matrix. In addition, numerical simulations are provided to demonstrate the merits of the proposed scheme.

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“…Many compensation methods have been proposed to reduce differences on the in situ RPs . However, they do not account for the effects of antenna thermal noise.…”

Section: Introductionmentioning

confidence: 99%

“…Many compensation methods have been proposed to reduce differences on the in situ RPs. [11][12][13][14] However, they do not account for the effects of antenna thermal noise. For a multiantenna GNSS receiver, each channel/antenna signal is essentially immersed into thermal noise that typically can be considered independent and identically distributed (i.i.d.)…”

Section: Introductionmentioning

confidence: 99%

Orthonormal method for compact Global Navigation Satellite Systems antenna array designs

Marranghelli

Valle

Roncagliolo

2019

Int J RF Microw Comput Aided Eng

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Compact antenna arrays require special considerations at design time not to degrade its efficiency and also the spatial diversity becomes reduced in terms of phase resolution as distance diminishes. Additionally, element radiation patterns are affected and the objective of equally behaved antennas is even more difficult to achieve. However, the induced antenna gain differences can actually be helpful because they can be used to maintain the degrees of freedom in array radiation pattern subspace. In this article, a general analysis on the relationship of efficiency and beam patterns are reviewed to prove that maximum efficiency is achieved when radiation patterns fulfill a given orthogonality condition. Under this condition, we propose to apply a unitary matrix transformation to the array response that can translate the compact antenna array behavior into the equivalent response of a λ2‐spaced ideal antenna array without modifying its total efficiency. Consequently, an useful compact antenna array should be designed to have orthogonal radiation beams. Then, applying the transformation, they can be translated to another orthogonal radiation patterns set with only phase differences and a common gain pattern. Simulated results of a computer‐aided design of a practical array of Global Navigation Satellite Systems microstrip antennas are presented.

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Unifying the Theory of Mutual Coupling Compensation in Antenna Arrays

Cited by 39 publications

References 86 publications

Investigation of a 256‐Monopole Transmit Antenna Array for Over‐the‐Horizon Radar in Canada

Investigation of a 256‐Monopole Transmit Antenna Array for Over‐the‐Horizon Radar in Canada

An Array Switching Strategy for Direction of Arrival Estimation with Coprime Linear Array in the Presence of Mutual Coupling

Orthonormal method for compact Global Navigation Satellite Systems antenna array designs

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