Intercell Wireless Communication in Software-defined Metasurfaces

Tasolamprou, Anna C.; Mirmoosa, M. S.; Tsilipakos, Odysseas; Pitilakis, Alexandros; Fu, Liu; Abadal, Sergi; Cabellos‐Aparicio, Albert; Alarcón, Eduard; Liaskos, Christos; Kantartzis, Nikolaos V.; Tretyakov, Sergei; Kafesaki, Maria; Economou, E. N.; Soukoulis, Costas M.

doi:10.1109/iscas.2018.8351865

Cited by 36 publications

(27 citation statements)

References 43 publications

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“…Beyond that, several authors have proposed to integrate a network of communicating chips within the metasurface containing actuators, control circuits, and even sensors [19], [21], [22], [62]. This concept, referred to as HyperSurface (HSF), opens new opportunities in the design of autonomous self-adaptive programmable metasurfaces but, at the same time, poses further challenges in the implementation, cointegration, and testing of the electronics within and around the metasurface.…”

Section: Background: Programmable Metasurfacesmentioning

confidence: 99%

Error Analysis of Programmable Metasurfaces for Beam Steering

Taghvaee

Cabellos‐Aparicio

Georgiou

et al. 2020

IEEE J. Emerg. Sel. Topics Circuits Syst.

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Recent years have seen the emergence of programmable metasurfaces, where the user can modify the EM response of the device via software. Adding reconfigurability to the already powerful EM capabilities of metasurfaces opens the door to novel cyber-physical systems with exciting applications in domains such as holography, cloaking, or wireless communications. This paradigm shift, however, comes with a non-trivial increase of the complexity of the metasurfaces that will pose new reliability challenges stemming from the need to integrate tuning, control, and communication resources to implement the programmability. While metasurfaces will become prone to failures, little is known about their tolerance to errors. To bridge this gap, this paper examines the reliability problem in programmable metamaterials by proposing an error model and a general methodology for error analysis. To derive the error model, the causes and potential impact of faults are identified and discussed qualitatively. The methodology is presented and exemplified for beam steering, which constitutes a relevant case for programmable metasurfaces. Results show that performance degradation depends on the type of error and its spatial distribution and that, in beam steering, error rates over 20% can still be considered acceptable.

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Section: Background: Programmable Metasurfacesmentioning

confidence: 99%

Error Analysis of Programmable Metasurfaces for Beam Steering

Taghvaee

Cabellos‐Aparicio

Georgiou

et al. 2020

IEEE J. Emerg. Sel. Topics Circuits Syst.

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“…Allowing a small amount of perturbation to the metasurface parameters, e.g. the dielectric thickness or the patch width, and/or freely choosing the intercell communication frequency band as fits best, and/or invoking microwave circuits to match |S 11 | at will, can lead to improved designs [31]. The main drawback in these approaches is the custom/non-standard ASICs (chips) required to compensate and even-out performance perturbations.…”

Section: B Discussionmentioning

confidence: 99%

“…In this paper, we undertake the thorough analysis of wireless mm-Wave intercell communication in the HSF environment, an important aspect of practical intelligent metasurfaces. In [31], we performed a preliminary assessment of the spectral characteristics of intercell communication in two specific channels and in the frequency domain. Here, we present a rigorous frequency and time domain study towards the exploration of the wireless communication channels within the landscape of a fully functional HSF, consisting of the components effectuating the EM manipulation of the wave, the MS layer and the controller chip.…”

Section: Introductionmentioning

confidence: 99%

“…In all channels, we evaluate the communication performance through frequencyand time-domain numerical calculations provid data for the channel transfer function, the mean delay and the delay spread. Technical considerations, detailed designs, analysis of obtained simulation results, and discussion are provided for each channel, separately, before drawing the overarching conclusions and outlook of the intercell communication exploration, compared to our preliminary study [31] in Section VI.…”

Section: Introductionmentioning

confidence: 99%

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Exploration of Intercell Wireless Millimeter-Wave Communication in the Landscape of Intelligent Metasurfaces

et al. 2019

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Software-defined metasurfaces are electromagnetically ultra-thin, artificial components that can provide engineered and externally controllable functionalities. The control over these functionalities is enabled by the metasurface tunability, which is implemented by embedded electronic circuits that modify locally the surface resistance and reactance. Integrating controllers within the metasurface cells, able to intercommunicate and adaptively reconfigure it, thus imparting a desired electromagnetic operation, opens the path towards the creation of an artificially intelligent (AI) fabric where each unit cell can have its own sensing, programmable computing, and actuation facilities. In this work we take a crucial step towards bringing the AI metasurface technology to emerging applications, in particular exploring the wireless mm-wave intercell communication capabilities in a software-defined HyperSurface designed for operation is the microwave regime. We examine three different wireless communication channels within the landscape of the reflective metasurface: Firstly, in the layer where the control electronics of the HyperSurface lie, secondly inside a dedicated layer enclosed between two metallic plates, and, thirdly, inside the metasurface itself. For each case we examine the physical implementation of the mm-wave transponder nodes, we quantify communication channel metrics, and we identify complexity vs. performance trade-offs.

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“…With this, we are able to assess whether data conversion will be a roadblock in the realization of the WNoC or not, and under which conditions. In a broader sense, the analysis would be applicable to other wireless applications with evident resource constraints such as Wireless Nanosensor Networks (WNSNs) [17] or Software-Defined Metamaterials (SDMs) [18]. In any case, and to the best of the author's knowledge, this is the first gap analysis relative to data conversion in emerging areaconstrained applications.…”

Section: Introductionmentioning

confidence: 99%

Data Conversion in Area-Constrained Applications: the Wireless Network-on-Chip Case

Abadal

Alarcón

2018

2018 Conference on Design of Circuits and Integrated Systems (DCIS)

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Network-on-Chip (NoC) is currently the paradigm of choice to interconnect the different components of Systemon-Chips (SoCs) or Chip Multiprocessors (CMPs). As the levels of integration continue to grow, however, current NoCs face significant scalability limitations and have prompted research in novel interconnect technologies. Among these, wireless intra-chip communications have been under intense scrutiny due to their low latency broadcast and architectural flexibility. Thus far, the practicality of the idea has been studied from the RF frontend and the network interface perspectives, whereas little to no attention has been placed on another essential component: the data converters. This article aims to fill this gap by providing a comprehensive analysis of the requirements of the scenario, as well as of the current performance and cost trends of Analogto-Digital Converters (ADCs). Based on Murmann's data, we demonstrate that ADCs will not be a roadblock for the realization of wireless intra-chip communications although current designs do not meet their demands fully.

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Intercell Wireless Communication in Software-defined Metasurfaces

Cited by 36 publications

References 43 publications

Error Analysis of Programmable Metasurfaces for Beam Steering

Error Analysis of Programmable Metasurfaces for Beam Steering

Exploration of Intercell Wireless Millimeter-Wave Communication in the Landscape of Intelligent Metasurfaces

Data Conversion in Area-Constrained Applications: the Wireless Network-on-Chip Case

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