Title :
Molecular Versus Electromagnetic Wave Propagation Loss in Macro-Scale Environments
Author :
Weisi Guo ; Mias, Christos ; Farsad, Nariman ; Jiang-Lun Wu
Author_Institution :
Sch. of Eng., Univ. of Warwick, Coventry, UK
fDate :
3/1/2015 12:00:00 AM
Abstract :
Molecular communications (MC) has been studied as a bio-inspired information carrier for micro-scale and nano-scale environments. On the macro-scale, it can also be considered as an alternative to electromagnetic (EM) wave based systems, especially in environments where there is significant attenuation to EM wave power. This paper goes beyond the unbounded free space propagation to examine three macro-scale environments: the pipe, the knife edge, and the mesh channel. Approximate analytical expressions shown in this paper demonstrate that MC has an advantage over EM wave communications when: 1) the EM frequency is below the cut-off frequency for the pipe channel, 2) the EM wavelength is considerably larger than the mesh period, and 3) when the receiver is in the high diffraction loss region of an obstacle.
Keywords :
approximation theory; electromagnetic wave attenuation; molecular communication (telecommunication); radio receivers; radiowave propagation; wireless channels; EM frequency; EM wave power; EM wavelength; bio-inspired information carrier; electromagnetic wave propagation loss; high diffraction loss region; knife edge; macroscale environments; mesh channel; microscale environment; molecular communications; molecular propagation loss; nanoscale environment; pipe channel; unbounded free space propagation; Apertures; Attenuation; Cutoff frequency; Gain; Receivers; Transmitters; Propagation; channel model; link budget; molecular communications; nano-communications; pathloss;
Journal_Title :
Molecular, Biological and Multi-Scale Communications, IEEE Transactions on
DOI :
10.1109/TMBMC.2015.2465517
