Page 50 - ITU Journal: Volume 2, No. 1 - Special issue - Propagation modelling for advanced future radio systems - Challenges for a congested radio spectrum
P. 50
ITU Journal: ICT Discoveries, Vol. 2(1), December 2019
of clutter and building entry loss on millimeter [5] C. Garcia-Pardo, A. Fornes-Leal, C. Andreu, N.
wave propagation have been presented from Cardona, S. Castello-Palacios, A. Valles-Lluch,
measurements at 26 GHz and the method proposed R. Chavez-Santiago, and I. Balasingham,
by ITU-R Recommendations for combining the two “Experimental Ultra Wideband Path Loss
losses was confirmed for the median value of Models for Implant Communications,”
building entry loss. THz propagation typical loss PIMRC’16, Valencia, Spain, Sep. 2016.
parameters are given. Although these high [6] L. Liu et al., "The COST 2100 MIMO channel
frequency bands are currently considered for short- model," in IEEE Wireless Commun., vol. 19,
range applications such as data centers, recently no. 6, pp. 92-99, Dec. 2012.
they have been proposed for car-to-X
communications and in intelligent transportation [7] J. Flordelis, X. Li, O. Edfors, F. Tufvesson,
systems where in railway environments various “Massive MIMO Extensions to the COST 2100
different propagation scenarios have been already Channel Model: Modeling and Validation”,
identified for smart rail applications. IEEE Trans. Wireless Commun., Under review.
https://arxiv.org/abs/1905.04931
ACKNOWLEDGEMENT [8] “COST 2100 channel model, public domain
The authors acknowledge the fruitful discussions in implementation,” available:
COST Action CA15104 IRACON. The authors would https://github.com/cost2100.
also like to thank all the contributors to the research [9] X. Li, E. Leitinger et al., “Massive MIMO- based
in the different institutions. localization and mapping exploiting phase
information of multipath components,” IEEE
REFERENCES Trans. Wireless Commun., 2019.
[1] K. Turbic, S. J. Ambroziak, and L. M. Correia, [10] D. Dupleich et al., "Multi-band
“Characteristics of the Polarised Off-Body Characterization of Path-loss, Delay, and
Channel in Indoor Environments,” EURASIP J. Angular Spread in V2V Links," Proc. PIMRC
Wireless Commun. Netw., vol. 2017, no. 1, 2018, Bologna, Italy, Sep. 2018.
p. 174, Oct. 2017.
[11] C. Gustafson, K. Mahler, D. Bolin, F. Tufvesson,
[2] S. J. Ambroziak, L. M. Correia, R. J. Katulski, M. “The COST IRACON Geometry-based
Mackowiak, C. Oliveira, J. Sadowski, and K. Stochastic Channel Model for Vehicle-to-
Turbic, “An Off-Body Channel Model for Body Vehicle Communication in Intersections”,
Area Networks in Indoor Environments,” IEEE Trans. on Vehicular Technology, Under
IEEE Trans. Antennas Propag., vol. 64, no. 9, review. http://arxiv.org/abs/1903.04788
pp. 4022–4035, Sep. 2016.
[12] M. Gudmundson, "Correlation model for
[3] P. T. Kosz, S. J. Ambroziak, J. Stefanski, K. K. shadow fading in mobile radio systems,"
Cwalina, L. M. Correia, and K. Turbic, “An Electron. Lett., vol. 27, no. 23, pp. 2145-2146,
Empirical System Loss Model for Body Area 7 Nov. 1991.
Networks in a Passenger Ferry Environment,”
in Proc. URSI’18 - Baltic URSI Symposium, [13] X. Raimundo, S. El-Faitori, and S. Salous,
Poznan, Poland, May 2018. Multi-band outdoor measurements in a
residential environment for 5G networks,
[4] C. Andreu, C. Garcia-Pardo, A. Fornes-Leal, N. EUCAP’18, London, UK, Apr. 2018.
Cardona, S. Castello-Palacios, and A. Valles-
Lluch, “Spatial In-Body Channel [14] IEEE Std for High Data Rate Wireless Multi-
Characterization Using an Accurate UWB Media Networks-Amendment 2: 100 Gb/s
Phantom,” IEEE Trans. on Microwave Theory Wireless Switched Point-to-Point Physical
and Techniques, vol. 64, no. 11, Layer," IEEE Std 802.15.3d-2017, vol., no.,
pp. 3995-4002, Nov. 2016 pp. 1-55, Oct. 2017
[15] Channel Modeling Document (CMD),”
https://mentor.ieee.org/802.15/dcn/14/15-
14-0310-18-003d-channel-modeling-
document.docx.
34 © International Telecommunication Union, 2019
