Performance evaluation of ITLinQ and FlashLinQ for overlaid device-to-device communication

We present a performance evaluation of ITLinQ/nand FlashLinQ, the two most popular schemes proposed to date/nto channelize D2D transmissions, i.e., to parse transmissions/ninto noninterfering sets to be allocated to separate channels./nRecognizing that it captures well the spatial characteristics of/nD2D networks, a stochastic geometry setting is utilized for this/nevaluation with the parameters of either scheme optimized in/norder to maximize the system spectral efficiency (bits/s/Hz per/nunit area). Although independently formulated and seemingly/nbased on different principles, both schemes are found to exercise/nsimilar mechanisms to avoid situations of excessive interference,/nyielding substantial improvements with respect to unchannelized/nnetworks.This work was supported in part by Intel’s University Research Program/n“5G: Transforming the Wireless User Experience”, by the MINECO Project/nTEC2012-34642 and by the National Science Foundation Grant No. 1218338

Performance evaluation of ITLinQ and FlashLinQ for overlaid device-to-device communication

We present a performance evaluation of ITLinQ/nand FlashLinQ, the two most popular schemes proposed to date/nto channelize D2D transmissions, i.e., to parse transmissions/ninto noninterfering sets to be allocated to separate channels./nRecognizing that it captures well the spatial characteristics of/nD2D networks, a stochastic geometry setting is utilized for this/nevaluation with the parameters of either scheme optimized in/norder to maximize the system spectral efficiency (bits/s/Hz per/nunit area). Although independently formulated and seemingly/nbased on different principles, both schemes are found to exercise/nsimilar mechanisms to avoid situations of excessive interference,/nyielding substantial improvements with respect to unchannelized/nnetworks.This work was supported in part by Intel’s University Research Program/n“5G: Transforming the Wireless User Experience”, by the MINECO Project/nTEC2012-34642 and by the National Science Foundation Grant No. 1218338