Propagation Mechanisms of Radio Waves Over Intra-Chip Channels With Integrated Antennas: Frequency-Domain Measurements and Time-Domain Analysis

Zhang, Yue Ping; Chen, Zhi Ming; Sun, Mengtao

doi:10.1109/tap.2007.905867

Cited by 93 publications

(69 citation statements)

References 14 publications

(26 reference statements)

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“…Propagation mechanisms of radio waves over intra-chip channels with integrated antennas were also investigated [3]. Indeed, zig-zag monopole antennas of axial length 1-2 mm can achieve a communication range of about 10-15 mm.…”

Section: B Physical Layer Designmentioning

confidence: 99%

Sustainability through massively integrated computing: Are we ready to break the energy efficiency wall for single-chip platforms?

Pande¹,

Clermidy²,

Puschini³

et al. 2011

2011 Design, Automation &Amp; Test in Europe

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-While traditional cluster computers are more constrained by power and cooling costs for solving extreme-scale (or exascale) problems, the continuing progress and integration levels in silicon technologies make possible complete end-user systems on a single chip. This massive level of integration makes modern multicore chips all pervasive in domains ranging from climate forecasting and astronomical data analysis, to consumer electronics, smart phones, and biological applications. Consequently, designing multicore chips for exascale computing while using the embedded systems design principles looks like a promising alternative to traditional clusterbased solutions. This paper aims to present an overview of new, farreaching design methodologies and run-time optimization techniques that can help breaking the energy efficiency wall in massively integrated single-chip computing platforms.

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Section: B Physical Layer Designmentioning

confidence: 99%

Sustainability through massively integrated computing: Are we ready to break the energy efficiency wall for single-chip platforms?

Pande¹,

Clermidy²,

Puschini³

et al. 2011

2011 Design, Automation &Amp; Test in Europe

View full text Add to dashboard Cite

show abstract

“…They have primarily used metal zig-zag antennas operating in the range of tens of GHz. The propagation mechanisms of radio waves over intra-chip channels with integrated antennas were also investigated [50]. It was shown that zig-zag monopole antennas of axial length 1-2 mm can achieve a communication range of about 10-15 mm.…”

Section: Wireless Nocmentioning

confidence: 99%

Networks-on-chip in emerging interconnect paradigms: Advantages and challenges

Carloni

Pande

Xie

2009

2009 3rd ACM/IEEE International Symposium on Networks-on-Chip

149

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“…Interconnects in multicore high performance computing architectures are the major drivers of such inconsistent requirements for design with mobile data cloud and intraroom multimedia [2, 4-9]; channel path loss quantification/model becomes necessary for specification of choice of channel bandwidths and any mitigation technique for channel distortion and interference such as equalization (e.g., filter) for adequate systems design. Attempts have been made by different researchers such as [1,[10][11][12][13][14][15][16] to model the propagation pattern in on-chips but less attention on interchip communication [13,17] and the general free space path loss model [18] remains unattended. Since interchip communication is key in system designs, then it becomes necessary to have an estimated path loss for adequate systems design.…”

Section: Introductionmentioning

confidence: 99%

Wireless Interconnect in Multilayer Chip-Area-Networks for Future Multimaterial High-Speed Systems Design

Famoriji

Khan

et al. 2017

Wireless Communications and Mobile Computing

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Wireless chip area network which enables wireless communication among chips fosters development in wireless communication and it is envisioned that future hardware system and developmental functionality will require multimaterial. However, the traditional system architecture is limited by channel bandwidth-limited interfaces, throughput, delay, and power consumption and as a result limits the efficiency and system performance. Wireless interconnect has been proposed to overcome scalability and performance limitations of multihop wired architectures. Characterization and modeling of channel become more important for specification of choice of modulation or demodulation techniques, channel bandwidths, and other mitigation techniques for channel distortion and interference such as equalization. This paper presents an analytical channel model for characterization, modeling, and analysis of wireless chip-to-chip or interchip interconnects in wireless chip area network with a particular focus on large-scale analysis. The proposed model accounts for both static and dynamic channel losses/attenuation in high-speed systems. Simulation and evaluation of the model with experimental data conducted in a computer desktop casing depict that proposed model matched measurement data very closely. The transmission of EM waves via a medium introduces molecular absorption due to various molecules within the material substance. This model is a representative of channel loss profile in wireless chip-areanetwork communication and good for future electronic circuits and high-speed systems design.

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Propagation Mechanisms of Radio Waves Over Intra-Chip Channels With Integrated Antennas: Frequency-Domain Measurements and Time-Domain Analysis

Abstract: Propagation mechanisms of radio waves over intra-chip channels with integrated antennas : frequency-domain measurements and time-domain analysis

Cited by 93 publications

References 14 publications

Sustainability through massively integrated computing: Are we ready to break the energy efficiency wall for single-chip platforms?

Sustainability through massively integrated computing: Are we ready to break the energy efficiency wall for single-chip platforms?

Networks-on-chip in emerging interconnect paradigms: Advantages and challenges

Wireless Interconnect in Multilayer Chip-Area-Networks for Future Multimaterial High-Speed Systems Design

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