ITU Journal on Future and Evolving Technologies, Volume 2 (2021), Issue 1



               RODENT:  A  flexible  TOPSIS  based  routing  protocol  for  multi-technology
               devices in wireless sensor networks
               Pages 89–100
               Brandon Foubert, Nathalie Mitton

               Wireless  Sensor  Networks  (WSN)  are  efficient  tools  for  many  use  cases,  such  as  environmental
               monitoring. However WSN deployment is sometimes limited by the characteristics of the Radio Access
               Technologies (RATs) they use. To overcome some of these limitations, we propose to leverage the use
               of a Multiple Technologies Network (MTN). What we refer to as MTN is a network composed of nodes
               which  are  able  to  use  several  RAT  and  communicating  wirelessly  through  multi-hop  paths.  The
               management of the RAT and routes must be handled by the nodes themselves, in a local and distributed
               way, with a suitable communication protocol stack. Nodes may reach multiple neighbors over multiple
               RAT.  Therefore,  each  stack's  layer  has  to  take  the  technologies'  heterogeneity  of  the  devices  into
               account.  In  this  article,  we  introduce  our  custom  Routing  Over  Different  Existing  Network
               Technologies protocol (RODENT), designed for MTN. It enables dynamic (re)selection of the best
               route and RAT based on the data type and requirements that may evolve over time, potentially mixing
               each technology over a single path. RODENT relies on a multi-criteria route selection performed with
               a  custom  lightweight  TOPSIS  method.  To  assess  RODENT's  performances,  we  implemented  a
               functional prototype on real WSN hardware, Pycom FiPy devices. Unlike related prototypes, ours has
               the advantage not to rely on specific infrastructure on the operator's side. Results show that RODENT
               enables energy savings, an increased coverage as well as multiple data requirements support.

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               A multi-link communication connectivity game under hostile interference
               Pages 101–112
               Andrey Garnaev, Wade Trappe, Narayan B. Mandayam, H. Vincent Poor
               In this paper, we consider a communication connectivity problem involving a primary user (transmitter,
               for example, a Ground Control Station (GCS)) servicing a group of secondary users (receivers, for
               example, drones) under hostile interference. We formulate this multi-link communication connectivity
               problem, where the channels are affected by Rayleigh fading, as a zero-sum power resource allocation
               game between a transmitter and an adversary (jammer). The transmitter's objective is to maximize the
               probability of communication connectivity with all the receivers. It is proven that the problem has
               unique  equilibrium  in  power  allocation  strategies,  and  the  equilibrium  is  derived  in  closed  form.
               Moreover, we reduce the problem of designing the equilibrium in power resource allocation strategies
               to the problem of finding a fixed point of a real-valued function. An algorithm based on the bisection
               method to find the fixed point (and so equilibrium strategies) is developed, and its convergence is
               proven.

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