Millimeter wave telecommunication technologies covering interdisciplinary areas, including health monitoring developments

Abstract

The paper considers the priority areas for the development of millimeter wave telecommunication technologies. The network services in demand, which cover interdisciplinary areas, such as fiber-ether network architecture, optoelectronic methods for generating radio signals, health monitoring and drug delivery systems based on mobile networks and intracellular nano-biosensor networks, are analyzed. The basis for the future development of telecommunications is the implementation of new applications in healthcare, security systems, control of robotic mechanisms, unmanned vehicles, in the field of distance education, entertainment and leisure. Modern research projects that are aimed at developing new technologies over 90 GHz for wireless communication systems with a bandwidth comparable to fiber-optic systems for implementing new applications are considered. Including health monitoring and diagnosis systems based on wearable nanobiosensing networks. The directions of further research in the field of the implementation of such systems are highlighted. The proposed architecture for the health care network is analyzed. It was highlighted that modern research covers the theoretical foundations of the mechanisms of communication between nanodevices, modern development of antennas, human tissue and channel modeling, design of environmental, epidemiological, and public health systems, including medical health monitoring. It has been shown that environmental and epidemiological monitoring, as well as health monitoring based on scientific achievements and research in the field of medical electronic technologies, telecommunications, including education, is a priority in interdisciplinary research, on the basis of which it is necessary to train the next generations of specialists.

Keywords: millimeter waves; telecommunication technologies; 5G; interdisciplinary research; health monitoring technologies; nanoscale networks.

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