Terahertz channel modeling of underground sensor networks in oil reservoirs

Akkaş, Mustafa Alper; Akyildiz, Ian F.; Sokullu, Radosveta

doi:10.1109/glocom.2012.6503169

Cited by 29 publications

(15 citation statements)

References 19 publications

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“…Absorption spectrum of water at various temperatures in the whole infrared (IR) region (0 < wave number ṽ< 4000 cm −1 ) can be obtained from attenuated total reflection spectra recorded in the mid-infrared region is combined with absorption spectra measured in the far-infrared region. Then, the absorption spectrum L water (in dB) of the EM waves in a sample of pure water within distance d can be calculated according to the Beer-Lambert law as in (8) [15,27,30]. In (8) medium is changed into the water, where d is the transmission distance; k water ( f ) is the absorption coefficient, which is a function of the operating frequency and is influenced by the liquid temperature.…”

Section: Numerical Results Of Channel Absorption Characteristicsmentioning

confidence: 99%

“…As the height of the fracture is <3 cm in oil reservoirs and 0.5 cm in hydraulic fracturing, the size of the sensor nodes should be in the millimetre magnitude. Furthermore, the millimetre scale sensor nodes necessitate antennas at the same scale which implies that the operating frequency has to be in the gigahertz or THz range [15,16]. These millimetre scale sensor nodes can also be used in underground water environment which has narrow height as in the oil recovery process and hydraulic fracturing.…”

Section: Ultra-compact Wireless Sensor Nodes Applicationmentioning

confidence: 99%

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Terahertz channel modelling of wireless ultra‐compact sensor networks using electromagnetic waves

Akkaş¹

2016

IET Communications

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Section: Numerical Results Of Channel Absorption Characteristicsmentioning

confidence: 99%

Section: Ultra-compact Wireless Sensor Nodes Applicationmentioning

confidence: 99%

Terahertz channel modelling of wireless ultra‐compact sensor networks using electromagnetic waves

Akkaş¹

2016

IET Communications

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“…The authors in [46] also compared the theoretical and measured results for UGWSNs where the above analytical model fits well within 3.45 dBm of the measured data. In [19] EM waves in Terahertz band (0.1-120 THz) were investigated for oil reservoirs. The path loss (in dB) for EM signals in the Terahertz band is given in [19] as follows…”

Section: A Channel Modelingmentioning

confidence: 99%

Toward the Internet of Underground Things: A Systematic Survey

Saeed

Alouini

Al-Naffouri

2019

IEEE Commun. Surv. Tutorials

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This paper provides recent advances in the area of Internet of Underground Things (IoUT) with emphasis on enabling communication technologies, networking issues, and localization techniques. IoUT is enabled by underground things (sensors), communication technology, and networking protocols. This new paradigm of IoUT facilitates the integration of sensing and communication in the underground environment for various industries, such as oil and gas, agriculture, seismic mapping, and border monitoring. These applications require to gather relevant information from the deployed underground things. However, the harsh underground propagation environment including sand, rock, and watersheds do not allow the use of single communication technology for information transfer between the surface and the underground things. Therefore, various wireless and wired communication technologies are used for underground communication. The wireless technologies are based on acoustic waves, electromagnetic waves, magnetic induction and visible light communication while the wired technologies use coaxial cable and optical fibers. In this paper, state-of-art communication technologies are surveyed, and the respective networking and localization techniques for IoUT are presented. Moreover, the advances and applications of IoUT are also reported. Also, new research challenges for the design and implementation of IoUT are identified.

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“…The channel model in Equation 10is used by the [37] to create a testbed for UGWSNs and [174] compares the theoretical and actual measured values in testbed. In [32,175], authors give the path loss formula in Terahertz band (0.1-120 THz) as follow:…”

Section: Em Channel Modelingmentioning

confidence: 99%

A Survey on Subsurface Signal Propagation

Raza

Salam

2020

Smart Cities

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Wireless Underground Communication (WUC) is an emerging field that is being developed continuously. It provides secure mechanism of deploying nodes underground which shields them from any outside temperament or harsh weather conditions. This paper works towards introducing WUC and give a detail overview of WUC. It discusses system architecture of WUC along with the anatomy of the underground sensor motes deployed in WUC systems. It also compares Over-the-Air and Underground and highlights the major differences between the both type of channels. Since, UG communication is an evolving field, this paper also presents the evolution of the field along with the components and example UG wireless communication systems. Finally, the current research challenges of the system are presented for further improvement of the WUCs.

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Terahertz channel modeling of underground sensor networks in oil reservoirs

Cited by 29 publications

References 19 publications

Terahertz channel modelling of wireless ultra‐compact sensor networks using electromagnetic waves

Terahertz channel modelling of wireless ultra‐compact sensor networks using electromagnetic waves

Toward the Internet of Underground Things: A Systematic Survey

A Survey on Subsurface Signal Propagation

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