@inproceedings{Banerjee2019,
   abstract = {Human interactions are different than physiological cellular interactions. However, there can be a direct relation made to show that the human movement is similar to the microscopic cellular movement and interactions. Generally, movement interferes with Device-to-Device (D2D) communication, resulting in under-performance when not achieving sufficient inter-contacts. In this context, we propose observing D2D communication as a resultant of human motion, mimicking cellular movement and user association affected by dense and normal User Equipment (UE) device distribution. Cellular movement in the context of this paper refers to biological cells, not wireless communication cells. The results of our work show an inherent relationship between throughput and cellular convex hull. To provide better insight over the biomimicry a new parameter is introduced to close the gap between irregular and regular cellular distribution, which in turn can decrease the complexity in decision making of resource allocation of D2D communication.},
   author = {S. Banerjee and M. Hempel and H. Sharif},
   doi = {10.1109/GLOCOMW.2018.8644461},
   isbn = {9781538649206},
   journal = {2018 IEEE Globecom Workshops, GC Wkshps 2018 - Proceedings},
   keywords = {D2D,biological,biomimicry,convex optimization,cvx,jamming,mobile,shape index,throughput,user association},
   title = {Human Interactions and User Association in Device-to-Device Communications in Terms of Biological Jamming},
   year = {2019},
}

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