Integrated dipole antennas and propagation channel on silicon in Ka band for WiNoC applications

Masri, Ihsan El; Gouguec, Thierry Le; Martin, Pièrre‐Marie; Allanic, Rozenn; Quendo, Cédric

doi:10.1109/sapiw.2018.8401659

Cited by 14 publications

(10 citation statements)

References 8 publications

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“…The difference between the -10 dB matching bandwidth in simulation F h1 -F l1 = 6.3 GHz (17.4%) and in measurement F h2 -F l2 = 11.1 GHz (30.8%) is due to the uncertainty on silicon losses, the antenna environment and the measurement conditions. [24] A good agreement between the simulated and measured S 12 transmission parameter is shown in Fig. 4.…”

Section: A Propagation Channel Measurements In Ka Bandsupporting

confidence: 54%

Accurate Channel Models for Realistic Design Space Exploration of Future Wireless NoCs

Masri

Martin

Mondal

et al. 2018

2018 Twelfth IEEE/ACM International Symposium on Networks-on-Chip (NOCS)

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Wireless Networks-on-Chip (WiNoC) are being explored for parallel applications to improve the performances by reducing the long distance/critical path communications. However, WiNoC still require precise propagation models to go beyond proof of concept and to demonstrate it can be considered as a realistic efficient alternative to wired NoC. In this paper, we present accurate 3D models based on measurements in Ka band and Electromagnetic (EM) simulations of transmission on silicon substrate in the V band and the Sub-THz band. Using these EM results, a time-domain simulation is performed using an On-Off Keying (OOK) modulation based transmission with different PA/LNA configurations. Our results highlight the type of performances and tradeoffs to be considered according to different parameters such as power output and amplifier's gain. By improving the knowledge about the signal propagation, one can conduct precise design space exploration for parallel applications. We discuss the realistic channel modeling and we present also hybrid solutions and associated limitations of WiNoC architectures. We conclude the paper with research directions to be explored to make WiNoC a reality.

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Section: A Propagation Channel Measurements In Ka Bandsupporting

confidence: 54%

Accurate Channel Models for Realistic Design Space Exploration of Future Wireless NoCs

Masri

Martin

Mondal

et al. 2018

2018 Twelfth IEEE/ACM International Symposium on Networks-on-Chip (NOCS)

Self Cite

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“…Works also exist in literature that model the wireless communication channel to simulate and to evaluate the WiNoC platform better and also to improve the network design. In [17], authors have proposed a multi-channel WiNoC platform and in [18], a communication channel in the Ka band is proposed to improve the on-chip communication of many-core chips. A parameterizable wireless channel model is proposed in [19] to evaluate the losses in WiNoC and to simulate the platform better.…”

Section: Winoc Without Securitymentioning

confidence: 99%

Attacks Toward Wireless Network-on-Chip and Countermeasures

Biswas

Chatterjee²,

Mondal³

et al. 2021

IEEE Trans. Emerg. Topics Comput.

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IntroductionA Wireless Network-on-Chip (WiNoC) offers a promising solution to reduce broadcast and long distance communication bottlenecks of conventional architectures by augmenting them with single hop wireless links. In this paper, we discuss new security vulnerabilities and countermeasures to protect against them in a WiNoC based system. In particular, we describe Malicious Threshold Configuration (MTC) Attack, Disruptive Token Passing (DTP) Attack, Data Stealing by Broadcast (DSB) Attack and Hybrid Attack against the WiNoC. Our proposed countermeasure against MTC-OU (over-utilization) attack i.e., Source Destination checking mechanism decreases wireless hub utilization by 49% and network latency by many orders of magnitude compared to without countermeasure, causing system performance improvement.Another proposed countermeasure against DTP attacks i.e., detour mechanism improves the network throughout by 1.21x and 23x under DTP-AHT and DTP-DOS attacks respectively.

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“…• Potentials: Network-on-Chips (NoCs) are central to the modern embedded cores and multiprocessor systems viable of a variety of domains and applications such as medical, consumer multimedia, image-processing, defence sector [195], artificial intelligence, scientific and multimedia applications [84], etc. Recently, the WNoC has emerged as a promising alternative for the conventional metallic interconnects based NoC and has been readily accepted to mitigate the large delay and high power dissipation issues offered by the NoC [195], [201]- [206].…”

Section: ) Wireless Network-on-chip (Wnoc) and Aocsmentioning

confidence: 99%

“…Recently, the WNoC has emerged as a promising alternative for the conventional metallic interconnects based NoC and has been readily accepted to mitigate the large delay and high power dissipation issues offered by the NoC [195], [201]- [206]. The WNoCs are also intended to promise several other advantages such as the lower complexity, compactness, enhanced efficiency, high performance, re-configurability [207], and routing flexibility [84]. Wireless transceiver and antenna are two core sections of such systems.…”

Section: ) Wireless Network-on-chip (Wnoc) and Aocsmentioning

confidence: 99%

The Potentials, Challenges, and Future Directions of On-Chip-Antennas for Emerging Wireless Applications—A Comprehensive Survey

et al. 2019

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The ever-growing demand for low power, high performance, cost-effective, low-profile, and highly integrated wireless systems for emerging applications has triggered the need for the enormous innovations in wireless transceiver systems, components, architectures and technologies. This is especially valid for the antenna which is an integral component of the wireless transceiver systems and contributes significantly in determining their overall performance. Antenna-on-Chip (AoC) is an alternative antenna technology, which has drawn a substantial attention in recent days because of its various benefits over off-chip antenna technology. A few of these benefits include miniaturization, low power, low cost, and high integration of the wireless modules. Motivated by these valuable advantages and to unveil the true potential of the AoCs, this article presents, for the first time, a comprehensive survey of the suitability, advantages, and challenges of the AoCs for the emerging wireless applications such as 5th generation (5G) Wireless Systems, Internet-of-Things (IoT) Wireless Devices and Systems, Wireless Sensor Networks (WSNs), Wireless Interconnects, Wireless Energy Transfer, Radio Frequency (RF) Energy Harvesting, Biomedical Implants, Unmanned Aerial Vehicles (UAVs), Autonomous vehicles, Innovative characterization methods for Integrated Circuits (ICs) and Antennas, and Smart City. In addition, this article presents the current stateof-the-art of the AoC's applications by classifying their applications in Millimeter-Wave (MM-Wave) band, Terahertz (THz) band, and low-frequency bands. The article also investigates and describes some useful methods for the mitigation of the challenges and issues posed by the emerging applications for the realization of the AoCs in a systematic manner. A concise description of the future directions of the AoCs with respect to each emerging application is also a part of this article. It is expected that this well-structured and organized survey will not only act as an excellent source of scholarship for the relevant research community, but also open up a world of novel research opportunities.

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Integrated dipole antennas and propagation channel on silicon in Ka band for WiNoC applications

Cited by 14 publications

References 8 publications

Accurate Channel Models for Realistic Design Space Exploration of Future Wireless NoCs

Accurate Channel Models for Realistic Design Space Exploration of Future Wireless NoCs

Attacks Toward Wireless Network-on-Chip and Countermeasures

The Potentials, Challenges, and Future Directions of On-Chip-Antennas for Emerging Wireless Applications—A Comprehensive Survey

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