Contributions to the Modeling and Design of Reconfigurable Reflecting Cells Embedding Discrete Control Elements

Abstract: Abstract-This paper presents new contributions to the modeling and design of reflecting cells embedding discrete control elements such as microelectromechanical system (MEMS) or diodes. First, a rigorous assessment of the different possibilities to simulate and measure the reconfigurable cell in a periodic environment is proposed. Strategies to efficiently model a cell comprising discrete control elements are then presented and discussed in terms of versatility, required assumptions, and computational effort. … Show more

“…In particular, the design of a lumped elements based cell can be carried out representing it by a multi-port scattering matrix where the effect of the lumped elements is included via circuitbased post-processing. This not only allows a single full-wave simulation of the cell for obtaining all the different states of the cell [48], but also allows for other interesting analyses such as the average or maximum voltage induced on each element [49] or some computation related to the sensitivity of the cell response to faults in the lumped control devices [50]. However it is worth noting here that accurate results require rigorous correction of parasitics related to the introduction of the lumped port in the full-wave simulator [48] [51].…”

“…This not only allows a single full-wave simulation of the cell for obtaining all the different states of the cell [48], but also allows for other interesting analyses such as the average or maximum voltage induced on each element [49] or some computation related to the sensitivity of the cell response to faults in the lumped control devices [50]. However it is worth noting here that accurate results require rigorous correction of parasitics related to the introduction of the lumped port in the full-wave simulator [48] [51]. Obviously, this separate computation of cell response and control elements is virtually impossible for technologies relying on the distributed control of some material property, which thus require full-wave solutions for each material state and provide fewer possibilities for advanced optimization methods.…”

“…Switches in the form of PIN diodes and micro-electrical-mechanical systems (MEMS) have been integrated with patches to control the current path and corresponding resonator length [40][59] [60]. Such methods depend on modelling techniques that allow for the analysis of the effect of tunable lumped element devices on the large scale electrical scattering characteristics of the device [48] [61]. In addition to using lumped element devices to effect changes in resonator lengths, more exotic techniques have also been contemplated, such as photo-induced plasmas for changing the length of slots coupled to reflectarray elements [32].…”

“…Indeed, while the modelling complexity of both approaches is quite similar (if the approach described in Section IV-A is used when addressing tunable resonator cells), the fact that the antenna and phase shifter can be optimized separately in the guided-wave approach results in simpler design procedure. For instance, in a digital design it is quite straightforward to achieve equi-spaced phase states in the guided-wave phase shifter, whereas doing so with a tunable resonator can require complex optimization which might still lead to sub-optimal phase distributions [48]. Another advantage of this technique is that wideband behavior is more easily obtained since simple guided-wave phase shifters can be designed to provide truetime delay capability.…”

Reconfigurable Reflectarrays and Array Lenses for Dynamic Antenna Beam Control: A Review

“…In particular, the design of a lumped elements based cell can be carried out representing it by a multi-port scattering matrix where the effect of the lumped elements is included via circuitbased post-processing. This not only allows a single full-wave simulation of the cell for obtaining all the different states of the cell [48], but also allows for other interesting analyses such as the average or maximum voltage induced on each element [49] or some computation related to the sensitivity of the cell response to faults in the lumped control devices [50]. However it is worth noting here that accurate results require rigorous correction of parasitics related to the introduction of the lumped port in the full-wave simulator [48] [51].…”

“…This not only allows a single full-wave simulation of the cell for obtaining all the different states of the cell [48], but also allows for other interesting analyses such as the average or maximum voltage induced on each element [49] or some computation related to the sensitivity of the cell response to faults in the lumped control devices [50]. However it is worth noting here that accurate results require rigorous correction of parasitics related to the introduction of the lumped port in the full-wave simulator [48] [51]. Obviously, this separate computation of cell response and control elements is virtually impossible for technologies relying on the distributed control of some material property, which thus require full-wave solutions for each material state and provide fewer possibilities for advanced optimization methods.…”

“…Switches in the form of PIN diodes and micro-electrical-mechanical systems (MEMS) have been integrated with patches to control the current path and corresponding resonator length [40][59] [60]. Such methods depend on modelling techniques that allow for the analysis of the effect of tunable lumped element devices on the large scale electrical scattering characteristics of the device [48] [61]. In addition to using lumped element devices to effect changes in resonator lengths, more exotic techniques have also been contemplated, such as photo-induced plasmas for changing the length of slots coupled to reflectarray elements [32].…”

“…Indeed, while the modelling complexity of both approaches is quite similar (if the approach described in Section IV-A is used when addressing tunable resonator cells), the fact that the antenna and phase shifter can be optimized separately in the guided-wave approach results in simpler design procedure. For instance, in a digital design it is quite straightforward to achieve equi-spaced phase states in the guided-wave phase shifter, whereas doing so with a tunable resonator can require complex optimization which might still lead to sub-optimal phase distributions [48]. Another advantage of this technique is that wideband behavior is more easily obtained since simple guided-wave phase shifters can be designed to provide truetime delay capability.…”

Reconfigurable Reflectarrays and Array Lenses for Dynamic Antenna Beam Control: A Review

“…Furthermore, the flatness, low-cost, and high-performance of a RA is well adapted for solar cell integration. Though this work focuses on fixed beam RAs, future development could consider the integration of beam scanning RAs [4][5] into solar panels thereby expending potential applications.…”

Design of a reflectarray element integrated in a Solar Cell panel

Design and Implementation of Parasitic Antenna Arrays for Beamspace-MIMO