Compact Broadband High-Directivity Microstrip Directional Coupler

Fabiani, B. M.; Sakomura, Eduardo S.; Gripp, Tarcisio A. B.; Nascimento, Daniel C.

doi:10.1590/2179-10742019v18i21521

Cited by 4 publications

(3 citation statements)

References 10 publications

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“…The directional coupler with high directivity presented in Figure 6A is a key element for the proper calibration of the proposed beamformer. The method for designing this component, in that a matching circuit is employed to compensate for the undesired effects caused by the difference between phase velocities of even and odd modes in microstrip couplers, is discussed in Reference 55 Figure 6B shows the measured frequency response of the prototype. As seen in this figure, it exhibits a return loss better than 30 dB, an average coupling of 17.5 dB, and a directivity greater than 35 dB from 2.0 to 2.4 GHz.…”

Section: Beamformer Prototypementioning

confidence: 99%

Closed‐loop controlled microwave beamformer

Fabiani

Oliveira

Vieira

et al. 2021

Int J RF Mic Comp-Aid Eng

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This article presents the design and tests of a closed‐loop controlled microwave beamformer for phased arrays. The proposed circuit owns an internal reference signal used to automatically set predefined amplitudes and phases of the beamformer branches. This signal is applied to the branches through directional couplers with high directivity and propagates in them similar to the actual signals coming from the antenna array. As a consequence of this architecture, we found that the impedance mismatch between the antennas and the beamformer as well as the mutual coupling in the array is taken into account during calibration, resulting in a more accurate adjustment of amplitudes and phases. In this work, the influence of the mutual coupling between the antennas and the directivity of the couplers on the beamforming calibration uncertainty is also analyzed. From the derived uncertainties, the corresponding pattern degradation is evaluated by performing Monte Carlo simulations. It is shown that using couplers with low directivity together with tightly coupled arrays can produce undesirable main lobe squints of up to 4.5°, main lobe level deviations of up to 4.2 dB, and side lobe level variations of up to 24 dB. On the other hand, the use of high directivity couplers can mitigate these problems. Lastly, the validation of the designed circuit is conducted in two stages: bench tests and measurements in an anechoic chamber with an array of six printed monopoles operating at 2.2 GHz. Amplitude and phase calibration errors less than 0.5 dB and 3°, respectively, were observed in the bench tests.

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Section: Beamformer Prototypementioning

confidence: 99%

Closed‐loop controlled microwave beamformer

Fabiani

Oliveira

Vieira

et al. 2021

Int J RF Mic Comp-Aid Eng

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“…In terms of the geometry any slot shape would provide similar results ranging from the rectangular ones to the dumbbell shape, therefore providing a reliable and easy to manufacture device with suitable S parameters [6].Furthermore, high variation in the geometry ,in terms of the slots between "U" or rectangularly shaped coupler is shown to decrease substantially return loss and isolation parameters, if the DGS is utilized [5][6].To overcome the mentioned deterioration one may perform extensive parametric study with tunning until the required results for the given geometry are obtained [6]. In terms of improved directivity one may utilize matching network design and therefore a compact directional coupler with less computationally demanding design is achieved [7].…”

Section: Introductionmentioning

confidence: 99%

“…In addition an improved directivity is observed if the microstrip coupler is subdivided into a symmetrical sections and by tunning and optimizing the overall width and height of the coupler and making it a quarter wavelength [7][8]. This in turn makes the stepped impedance coupler and due to the symmetrical structure it is simple to design and tune, which makes the coupler with the improved directivity inexpensive [8].…”

Section: Introductionmentioning

confidence: 99%

2.3 GHz Microstrip Rectangular Structured Hybrid Coupler for WiMax applications

Ramdedovic

Imeci

2023

Preprint

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The paper depicts a symmetric microstrip coupler designed for WiMax applications in the frequency range of 2.32 - 2.52GHz. The proposed coupler is comprised of four resonator structures attached in parallel to the ports providing lowered isolation and increased insertion loss and coupling factor. Furthermore, the presented microstrip coupler is simulated utilizing the Sonnet Suites software with the numerical approximation of the mathematical derivation of MoM (Method of Moments) for the symmetrical structure. The simulated and fabricated results show high resemblance with the data acquired after the simulation with input match being below -20dB, insertion loss and coupling factor almost -3.0 dB and isolation factor below -50dB. Approximate values of the measured design are -15.48dB, -3.86dB and -46.63dB respectively Moreover, the dielectric substrate utilized for the proposed geometry of the microstrip coupler is FR4 with ε_r=4.4 with thickness of 1.55mm.The proposed coupler is relatively inexpensive, reliable in the provided frequency range and could be used in wireless communication applications.

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Broadband Microstrip Directional Coupler using capacitive compensation and matching networks

Torres-Quispe

Zenteno

2022

2022 IEEE XXIX International Conference on Electronics, Electrical Engineering and Computing (INTERCON)

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Compact Broadband High-Directivity Microstrip Directional Coupler

Cited by 4 publications

References 10 publications

Closed‐loop controlled microwave beamformer

Closed‐loop controlled microwave beamformer

2.3 GHz Microstrip Rectangular Structured Hybrid Coupler for WiMax applications

Broadband Microstrip Directional Coupler using capacitive compensation and matching networks

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