Bandwidth Considerations for a Microstrip Reflectarray

Bialkowski, M.E.; Sayidmarie, Khalil H.

doi:10.2528/pierb07120405

Cited by 39 publications

(45 citation statements)

References 15 publications

(18 reference statements)

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“…MRAs inherently have narrow bandwidth which is essentially caused by two parameters: the inherent narrow bandwidth of the microstrip array elements, and the frequency dependency of the phase delay of the radiated field from the horn antenna upon the array elements [39,40]. In recent years, variety of methods has been used for bandwidth enhancement of MRAs.…”

Section: Introductionmentioning

confidence: 99%

A Novel Bandwidth Enhancement Technique for X-Band Rf Mems Actuated Reconfigurable Reflectarray

Ra’di¹,

Nikmehr²,

Poorziad³

2011

PIER

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Abstract-In this paper, a wideband microstrip antenna for Xband (8.2 GHz-12.4 GHz) applications is introduced. First, simple patch antennas are studied, and a narrowband reflectarray antenna is designed. The resultant design demonstrates better performance than the previously published narrowband microstrip reflectarray antennas. The important features of the employed elements are simple structure, linear operation, and use of Radio Frequency Micro Electro Mechanical Systems (RF MEMS) switches for programmable pattern control. Next, employing our novel method, the designed narrowband structure is converted to broadband reflectarray antenna that can cover the whole X band. This novel idea is based on introducing several ground plane slots and controlling their electrical lengths by RF MEMS switches. By means of this method, 952 and 587 degree phase swing are achieved for continuous and discrete slot length variations, respectively. Application of this method along with smaller switches results in phase swing improvement of up to 1616 degree. In all structures a RT duroid (5880) substrate is selected to lower the back radiation. The achieved return loss in all cases is less than 0.32 dB. In comparison with the previous publications, our novel bandwidth enhancement technique has more generalization capability and results in single layered broadband reconfigurable microstrip reflectarray antennas with linear phase swing, lower cost, and ease of RF MEMS implementation.

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Section: Introductionmentioning

confidence: 99%

A Novel Bandwidth Enhancement Technique for X-Band Rf Mems Actuated Reconfigurable Reflectarray

Ra’di¹,

Nikmehr²,

Poorziad³

2011

PIER

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“…Because the phase characteristic acquired for the normal wave incidence provides a good approximation for the cases of TE and TM wave incidence for an angle up to 30 • from the reflectarray boresight direction [19], normal wave incidence is considered to obtain phase characteristic. The interaction of a normal incidence plane wave with the reflectarray can be modeled numerically by a unit cell waveguide approach (WGA) [19,20]. As displayed in Fig.…”

Section: Design Of Reflectarray Antenna Elementmentioning

confidence: 99%

A Reflectarray Antenna Backed on FSS for Low RCS and High Radiation Performances

Li¹,

Wang²,

Zheng³

et al. 2010

PIER C

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Abstract-This paper investigates the application of frequencyselective surface (FSS) in reflectarray antennas for the purpose of reducing radar cross section (RCS) level. Different from previous reports, the presented band-stop FSS structure is also characterized by the suppression of surface waves, which makes a contribution to better radiation performance. Two 14×14 reflectarray antennas backed on the FSS ground and a solid ground are designed and fabricated. Simulated and measured results show that the FSS ground can improve the 'inband' gain by 1.1 dB, decrease the sidelobe level by 6.4 dB, and reduce the 'out-of-band' RCS effectively when compared with the antenna with a solid ground plane of the same size.

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“…This assumption is reasonable since the inter-element spacing is usually a small fraction of λ 0 (which is much lower than D/2). Furthermore, as in [9] and [10] and for simplicity reasons, S i and the resulting σ S are calculated for a centered fed RA. Different expressions could easily be established for offset configurations.…”

Section: Standard Deviation Of Incident Phase Errorsmentioning

confidence: 99%

“…The suggested approach relies on the standard deviation of phase errors over the RA panel and combines the effects of both bandwidth limiting factors: the dispersion of spatial phase delays with frequency [9] and the intrinsic limited bandwidth of cells themselves [10]. This standard deviation is shown to provide a promising figure of merit, better than those in [9,10] where only the maximum phase error due to spatial delays is taken into account.…”

Section: Introductionmentioning

confidence: 99%

A Statistical Approach for Gain Bandwidth Prediction of Phoenix-Cell Based Reflect arrays

Salti¹,

Gillard²

2018

Adv. sci. technol. eng. syst. j.

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Bandwidth Considerations for a Microstrip Reflectarray

Cited by 39 publications

References 15 publications

A Novel Bandwidth Enhancement Technique for X-Band Rf Mems Actuated Reconfigurable Reflectarray

A Novel Bandwidth Enhancement Technique for X-Band Rf Mems Actuated Reconfigurable Reflectarray

A Reflectarray Antenna Backed on FSS for Low RCS and High Radiation Performances

A Statistical Approach for Gain Bandwidth Prediction of Phoenix-Cell Based Reflect arrays

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