IEEE 802.15.3c: the first IEEE wireless standard for data rates over 1 Gb/s

Baykaş, Tunçer; Sum, Chin-Sean; Zhou, Lan; Wang, Junyi; Rahman, M.A.; Harada, Hiroshi; Kato, S.

doi:10.1109/mcom.2011.5936164

Cited by 269 publications

(140 citation statements)

References 3 publications

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“…According to [2], the available spectrum for cellular communications at the mmWave band can be easily 200 times greater than the spectrum presently allocated for this purpose below the 3 GHz [2]. The mmWave band ranging from 30 − 300 GHz has already been considered for wireless services such as fixed access and personal area networking [4,5]. However, such frequency bands have long been deemed unsuitable for cellular communications due to the large free space pathloss and poor penetration (i.e., blockage effect) through materials such as water and concrete.…”

Section: Introductionmentioning

confidence: 99%

Coverage and rate analysis in the uplink of millimeter wave cellular networks with fractional power control

Onireti

Imran

2018

J Wireless Com Network

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In this paper, using the concept of stochastic geometry, we present an analytical framework to evaluate the signal-to-interference-and-noise-ratio (SINR) coverage in the uplink of millimeter wave cellular networks. By using a distance-dependent line-of-sight (LOS) probability function, the location of LOS and non-LOS users are modeled as two independent non-homogeneous Poisson point processes, with each having a different pathloss exponent. The analysis takes account of per-user fractional power control (FPC), which couples the transmission of users based on location-dependent channel inversion. We consider the following scenarios in our analysis: (1) pathloss-based FPC (PL-FPC) which is performed using the measured pathloss and (2) distance-based FPC (D-FPC) which is performed using the measured distance. Using the developed framework, we derive expressions for the area spectral efficiency. Results suggest that in terms of SINR coverage, D-FPC outperforms PL-FPC scheme at high SINR where the future networks are expected to operate. It achieves equal or better area spectral efficiency compared with the PL-FPC scheme. Contrary to the conventional ultra-high frequency cellular networks, in both FPC schemes, the SINR coverage decreases as the cell density becomes greater than a threshold, while the area spectral efficiency experiences a slow growth region.

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Section: Introductionmentioning

confidence: 99%

Coverage and rate analysis in the uplink of millimeter wave cellular networks with fractional power control

Onireti

Imran

2018

J Wireless Com Network

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“…In recent years, many foreign academic communities and enterprise alliances were opened for the research of the 60GHz pulse wireless communication technology. But the research is mainly focused on the design of transceiver [16,18,21], the establishment of channel model [2,9], the standards the physical layer and MAC layer of communication [10], the transceiver antenna beam shaping [12,13,26] and so on. Currently, the research of the 60GHz pulse positioning is still relatively deficient, and lack of an integral theoretical system.…”

Section: Introductionmentioning

confidence: 99%

Indoor precise positioning algorithm using 60GHz pulse based on compressive sensing

Han¹,

Wang²,

Shi³

et al. 2016

J. Math. Computer Sci.

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Aiming at the existing defect of poor positioning accuracy in NLOS (Non Line of Sight) environment for most of the common indoor positioning algorithms, this paper proposes a precise indoor positioning algorithm using 60GHz pulse based on compressed sensing. The proposed algorithm converts the location of the target nodes in the area to be located into a sparse vector and designs the over-completed dictionary using TOA (Time of Arrival)-based ranging, then takes advantage of the l 1 -minimization to reconstruct the location of the target nodes. The algorithm divides the positioning process into coarse positioning and fine positioning, and introduces the reference node selection mechanism in fine positioning. The algorithm not only can achieve the positioning of single target, but also achieve the positioning of multiple targets. Through the theoretical analysis and experiment simulation results, we can conclude that the proposed algorithm using 60GHz pulse can achieve precise indoor positioning in NLOS environment and centimeter-level positioning precision can be obtained compared with TOA based 60GHz geometric positioning algorithm.

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“…Consequently, devices are expected to achieve multi-Gbps data rates and will be capable of supporting bandwidth intensive, upcoming applications such as uncompressed High-Definition Television (HDTV). Moreover, mmWave links are ideal replacements for wires that interconnect a computer and its external peripherals, and also allow users to exchange audio/video files over an ad-hoc network [4]. Consequently, 60 GHz is a key enabler of future, gigabits wireless networks, which encompasses next generation cellular communications [28] and body area networks [5].…”

Section: Introductionmentioning

confidence: 99%

“…Advantageously, the millimeter wavelength allows multiple elements to be placed on a device [4], which in turn enables Spatial Division Multiple Access (SDMA) and high gains. However, this requires expensive multiple Radio Frequency (RF) chains.…”

Section: Introductionmentioning

confidence: 99%

A survey of single and multi-hop link schedulers for mmWave wireless systems

Song

Chin

2015

Ad Hoc Networks

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Wireless communication at 60. GHz, aka mmWave, provides extremely high data rates, i.e., several Gb/s. Moreover, devices have a much shorter transmission range as compared to those operating in the 2.4 and 5. GHz bands. Indeed, links can be treated as pseudo-wires with minimal interference leakage. As a result, future 60. GHz systems will have very high spatial reuse. This, however, is at the expense of high propagation loss, which can be overcome using directional or smart antennas. Another promising solution is to employ relays to boost the signal of weak links. In particular, if relays are properly selected, they are able to offer higher data rates than direct links, and also help circumvent obstacles. To this end, we review state-of-the-art schedulers that take advantage of the high spatial re-use afforded by 60. GHz wireless systems to activate multiple links within a channel time allocation. Moreover, we survey works that use passive and active relays to overcome obstacles and to facilitate novel applications. We also survey those that maximize both spatial reuse and throughput of both direct and indirect (relay) links simultaneously. Wireless communication at 60 GHz, aka mmWave, provides extremely high data rates, i.e., several Gb/s. Moreover, devices have a much shorter transmission range as compared to those operating in the 2.4 and 5 GHz bands. Indeed, links can be treated as pseudo-wires with minimal interference leakage. As a result, future 60 GHz systems will have very high spatial reuse. This, however, is at the expense of high propagation loss, which can be overcome using directional antennas. Another promising solution is to employ relays to forward data from senders to receivers. In particular, if relays are properly selected, they are able to offer higher data rates than direct links, and also help circumvent obstacles. To this end, we review state-of-the-art schedulers that take advantage of the high spatial re-use afforded by 60 GHz wireless systems to activate multiple links within a channel time allocation. Moreover, we survey works that use passive and active relays to overcome obstacles and facilitate novel applications. We also survey those that maximize both spatial reuse and throughput of both direct and indirect (relay) links simultaneously.

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IEEE 802.15.3c: the first IEEE wireless standard for data rates over 1 Gb/s

Cited by 269 publications

References 3 publications

Coverage and rate analysis in the uplink of millimeter wave cellular networks with fractional power control

Coverage and rate analysis in the uplink of millimeter wave cellular networks with fractional power control

Indoor precise positioning algorithm using 60GHz pulse based on compressive sensing

A survey of single and multi-hop link schedulers for mmWave wireless systems

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