Development of the Transmitting and Receiving Channels for Terahertz Band Relay Systems

Ilchenko, M. E.; Narytnyk, T. M.; Radzikhovsky, B.M.; Kuzmin, S.Ye.; Lutchak, O. V.

doi:10.1615/telecomradeng.v74.i11.30

Cited by 3 publications

(1 citation statement)

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“…To provide for outside transmission of the aggregated channel with the bitrate of 600 Mbps, the RB750 group router has to be replaced with the router having the throughput capacity of 1 Gbps and more, for example, with RB 450G or RB1100Hx2 that is envisaged by the modem design. The 130…134 GHz gigabit telecommunication system based on the Wi-Fi technology tested in vitro on the experimental equipment with attaining of the channel bitrate of up to 1.2 Gbps is suggested with using the G1 gigabit modem with the installed Mikrotik R52n-M transceivers and the developed transmitting and receiving paths [25] with application of the Wi-Fi technology.…”

Section: Fig 9: Photographic Image Of Test Specimen Of the G1 Gigabimentioning

confidence: 99%

Criteria and Algorithms for Shaping of the Signal-Code Sequences on the Basis of Wi-Fi Technology at Deployment of the Terahertz Band Telecommunication System

et al. 2015

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The principles of a signal-code sequence shaping are considered, the means and new technologies for selection of the type of the signal sequence are suggested in order to attain the best throughput and efficiency parameters in the telecommunication channel of a wireless data transmission system where the performance is determined by the signal-to-noise ratio at the input of the receiver. Based on the analysis of parameters and criteria recommended by IEEE 802.11а/n specifications for selection of the signal-code sequences, it is suggested the informational efficiency parameter for using the telecommunication channel resources. The telecommunication line was tested to the range of 1.7 km with the help of MikroTik R52n-M wireless interfaces. There were defined the signal-code sequences, which were selected for data transmission by the software-defined radio systems. It was determined that judging upon the signal level at the input of the receiver, types of the signal-code sequence and the obtained data transmission rate, the software-defined radio system using the MikroTik R52n-M equipment is fully compliant with the recommendations provided in IEEE 802.11а/n specifications. Realization of the concept for creation of a Wi-Fi-based software-defined radio systems is demonstrated on the example of a developed gigabit data transmission system in the 130…134 GHz bandwidth of the terahertz band. The system was tested in vitro where it attained the data transmission rate of up to 1.2 Gbps. It is demonstrated that the above data transmission system can be potentially used in transportation and distribution networks for the next generation mobile communication networks providing for the required bitrate, reliability and protection.

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Section: Fig 9: Photographic Image Of Test Specimen Of the G1 Gigabimentioning

confidence: 99%

Criteria and Algorithms for Shaping of the Signal-Code Sequences on the Basis of Wi-Fi Technology at Deployment of the Terahertz Band Telecommunication System

et al. 2015

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Radioelectronic Devices and Systems of Radio Communication and Short-range Radar in the Terahertz Frequency Range for High-speed Data Transmission, Guidance and Control

Avdeyenko,

Narytnyk,

Ilchenko

2023

2023 IEEE International Conference on Information and Telecommunication Technologies and Radio Electronics (UkrMiCo)

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Space infrastructure of the Internet of things. State and prospects of development

Ilchenko¹,

Narytnyk²,

Prysiazhnyi³

et al. 2021

Kosm. nauka tehnol.

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We present an overview of possibilities for existing Satellite Communication Systems utilization to provide Internet of Things Services. It is shown that existing Satellite Communication Systems provide traffic transmission for IoT Systems with Cloud Architecture. The proposals are explicated on the possibility of using Fog and Edge Computing for Satellite Communication Systems. The implementation of Fog and Edge computing in IoT Systems requires the modernization of the Low-Earth Orbit (LEO) and Geostationary Orbit (GEO) Satellite Communication Systems, and we show the ways of their enhancement. To increase the efficiency of IoT data processing and the reliability of IoT Data Storage, we propose to construct an Orbital Cloud Data Storage in GEO, which consists of several GEO Satellites - Cloud Computing Data Centers. Such a structure would require the development of methods of access providing to the Orbital Cloud Data Storage. For these purposes, our propositions include using GEO High-Throughput Satellites and satellites from the structure of LEO Satellite Communication. The issues of interaction between Orbital Cloud Data Storage and ground-based Cloud Data Processing and Storage Infrastructure are briefly considered. The orbital slots in GEO are proposed for the location of GEO Satellites - Cloud Computing Data Centers.

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Development of the Transmitting and Receiving Channels for Terahertz Band Relay Systems

Cited by 3 publications

References 0 publications

Criteria and Algorithms for Shaping of the Signal-Code Sequences on the Basis of Wi-Fi Technology at Deployment of the Terahertz Band Telecommunication System

Criteria and Algorithms for Shaping of the Signal-Code Sequences on the Basis of Wi-Fi Technology at Deployment of the Terahertz Band Telecommunication System

Radioelectronic Devices and Systems of Radio Communication and Short-range Radar in the Terahertz Frequency Range for High-speed Data Transmission, Guidance and Control

Space infrastructure of the Internet of things. State and prospects of development

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