| Analysis of adjacent channel interference using distribution function for V2X communication systems in the 5.9-GHz band for ITS |
|
Song, Yoo Seung
(Artificial Intelligence Research Laboratory, Electronics and Telecommunications Research Institute)
Lee, Shin Kyung (Artificial Intelligence Research Laboratory, Electronics and Telecommunications Research Institute) Lee, Jeong Woo (Artificial Intelligence Research Laboratory, Electronics and Telecommunications Research Institute) Kang, Do Wook (Artificial Intelligence Research Laboratory, Electronics and Telecommunications Research Institute) Min, Kyoung Wook (Artificial Intelligence Research Laboratory, Electronics and Telecommunications Research Institute) |
| 1 | M.K. Simon and M.S. Alouini, Digital communication over fading channels, Wiley-IEEE Press, Hoboken, NJ, USA, 2005, p. 24. |
| 2 | K. Aldana, U.S. Department of Transportation Releases Policy on Automated Vehicle Development, NHTSA, US Department of Transportation, 2013. Accessed Dec. 13, 2018. https://www.transporta tion.gov/briefing-room. |
| 3 | SAE J3016, Taxonomy and definitions for terms related to driving automation systems for on-road motor vehicles, SAE International, Warrendale, PA, USA, Sept. 2016. |
| 4 | 3GPP TR 22.886 v15.1.0, 3rd generation partnership project; Technical specification group services and system aspects; Study on enhancement of 3GPP support for 5G V2X services (Release 15), Valbonne, France, Mar. 2017. |
| 5 | ETSI TR 102 638 v1.1.1, Intelligent transport systems (ITS); Vehicular communications; Basic set of applications; Definitions, Sophia Antipolis Cedex, France, June 2009. |
| 6 | ETSI 302 637-2 v1.3.1, Intelligent transport systems (ITS); Vehicular communications; Basic set of application; Part2: Specification of cooperative awareness basic service, Sophia Antipolis Cedex, France, Sept. 2014. |
| 7 | ETSI 302 637-3 v1.2.1, Intelligent transport systems (ITS); Vehicular communications; Basic set of application; Part3: specification of decentralized environmental notification basic service, Sophia Antipolis Cedex, France, Sept. 2014. |
| 8 | IEEE802.11, IEEE standard for information technology-telecommunication and information exchange between systems local and metropolitan area networks specific requirements Part11: Wireless LAN medium access control (MAC) and physical layer (PHY) specifications, IEEE, Piscataway, NJ, USA, 2012. |
| 9 | SAE J2735, Dedicated short range communications (DSRC) message set dictionary, SAE International, Warrendale, PA, USA, Nov. 2009. |
| 10 | Preliminary draft revision of recommendation ITU-R M.2084-0, Radio interface standards of vehicle-to-vehicle and vehicle-toinfrastructure communications for Intelligent Transport Systems applications, International Telecommunication Union, Sept. 2015. |
| 11 | IEEE1609.2, IEEE standard for wireless access in vehicular environments-security services for applications and management messages, IEEE, New York, NY, USA, 2016. |
| 12 | Qualcomm, Accelerating C-V2X commercialization, Sept. 2017, Accessed Dec. 13, 2018. http://www.qualcomm.com |
| 13 | IEEE1609.3, IEEE standard for wireless access in vehicular environments(WAVE) - networking services, IEEE, New York, NY, USA, 2016. |
| 14 | IEEE1609.4, IEEE standard for wireless access in vehicular environments (WAVE) - multi-channel operation, IEEE, New York, NY, USA, 2016. |
| 15 | 3GPP TR 36.885 v14.0.0, Study on LTE based V2X services (Release 14), Valbonne, France, June 2016. |
| 16 | 5GAA (5G Automotive Association), The case for cellular V2X for safety and cooperative driving, Nov. 2016. |
| 17 | K. Xiong et al., Mobile service amount based link scheduling for high-mobility cooperative vehicular networks, IEEE Trans. Veh. Technol. 66 (2017), 9521-9533. DOI |
| 18 | H.K. Son and C.Y. Kim, Derivation of probability function of signal- to-interference-plus-noise ratio for the MS-to-MS interference analysis, Scientific World J. 2013 (2013), 1-6. |
| 19 | J. Me et al., A latency and reliability guaranteed resource allocation scheme for LTE V2V communication systems, IEEE. Trans. Wireless Commun. 17 (2018), 3850-3860. DOI |
| 20 | B.P. Tewari and S.C. Ghosh, Combined power control and Partially overlapping channel assignment for interference mitigation in dense WLAN, in Proc. IEEE Int. Conf. AINA, Taipei, Taiwan, May 27-29, 2017, pp. 646-653. |
| 21 | C. Campolo et al., On the impact of adjacent channel interference in multi-channel VANETs, in Proc. IEEE Int. Conf. Commun., Kuala Lumpur, Malaysia, May 23-27, 2016, pp. 1-7. |
| 22 | W.Y. Yeo, S.H. Moon, and J.H. Kim, Uplink scheduling and adjacent channel coupling loss analysis for TD-LTE deployment, Scientific World J. 2014 (2014), 1-15. |
| 23 | A.M. Voicu et al., Analyzing Wi-Fi/LTE coexistence to demonstrate the value of risk-informed interference assessment, in Proc. IEEE DySPAN, Piscataway, NJ, USA, Mar. 6-9, 2017, pp. 1-10. |
| 24 | Y.P. Wang and K.H. Chang, Adjacent channel interference reduction for M-WiMAX TDD and WCDMA FDD coexistence by utilizing beamforming in M-WiMAX TDD system, IEICE Trans. Commun. E93-B (2010), no. 1, pp. 111-124. DOI |
| 25 | K. Xiong et al., A broad beamforming approach for high-mobility communications, IEEE Trans. Veh. Technol. 66 (2017), no. 11, 10546-10550. DOI |
| 26 | Y. Lu et al., Optimal multi-cell coordinated beamforming for downlink high-speed railway communications, IEEE Tran. Veh. Technol. 66 (2017), 9603-9608. DOI |
| 27 | A. Tekovic et al., Interference analysis between mobile radio and digital terrestrial television in the digital dividend spectrum, Radio Eng. 26 (2017), no. 1, 211-220. |
| 28 | Y.K. Yoon and Y.J. Chong, Outage performance and derivation due to adjacent channel interference, in Proc. Int. Conf. Wireless Mobile Commun. (ICWMC), Seville, Spain, June 22-26, 2014, pp. 10-13. |
| 29 | G. Naik, J.S. Liu, and J.M. Park, Coexistence of wireless technologies in the 5 GHz bands: a survey of existing solutions and a roadmap for future research, IEEE Commun. Surveys Tutorials 20 (2018), no. 3, 1-22. DOI |
| 30 | M.J. Kim et al., Modeling of adjacent channel interference in heterogeneous wireless networks, IEEE Commun. Lett. 17 (2013), no. 9, 1174-1777. |
| 31 | R.W. Heath, M. Kountouris, and T. Bai, Modeling heterogeneous network interference using poisson point processes, IEEE Trans. Signal Process. 61 (2013), no. 16, 4114-4126. DOI |
| 32 | S.P. Damodaran and M. Pazha, Analysis of interference modeling and coexistence for next-generation LTE cellular systems, in Proc. Int. Conf. Commun. Process. (ICCSP), Melmaruvathur, India, Apr. 2-4, 2015, pp. 1608-1611. |
| 33 | R. Lasowski et al., Evaluation of adjacent channel interference in single radio vehicular Ad-Hoc networks, in IEEE Consumer Commun. Netw. Conf. (CCNC), Las Vegas, NV, USA, Jan. 9-12, 2011, pp. 267-271. |
| 34 | V. Angelakis et al., Adjacent channel interference in 802.11a is harmful: testbed validation of a simple quantification model, IEEE Commun. Mag. 49 (2011), no. 3, 160-166. DOI |
| 35 | A. Mishra et al., Partially overlapped channels not considered harmful, in Proc. Joint Int. Conf. Meas. Modeling Comput. Syst. (SIGMETRICS), Saint Malo, France, June 26-30, 2006, pp. 63-74. |
| 36 | A.M. Voicu, L. Simic, and M. Petrova, Inter-technology coexistence in a spectrum commons: a case study of Wi-Fi and LTE in the 5-GHz unlicensed band, IEEE J. Selected Areas Commun. 24 (2016), no. 11, 3062-3077. |
| 37 | Y.S. Song and J.D. Choi, V2X throughputs based on link budget analysis for 5.8GHz WAVE systems, in Proc. IEEE ICTC Conf., Jeju, Rep. of Korea, Oct. 28-30, 2015, pp. 981-985. |
| 38 | D. Hu and S. Mao, Ad Hoc Networks: on co-channel and adjacent channel interference mitigation in cognitive radio networks, Elsevier Science Ltd, Amsterdam, Netherlands, 2013, pp. 1629-1640. |
| 39 | A.F. Molisch et al., On pathloss models for adjacent-channel interference in cognitive whitespace systems, in Proc. IEEE Int. Conf. Commun. Workshops (ICC), Kuala Lumpur, Malaysia, May 23- 27, 2016, pp. 682-688. |
| 40 | G.R. Cooper and C.D. McGillem, Probabilistic methods of signal and system analysis, 3rd ed., Oxford University Press, NY, USA, 1998. |
| 41 | 3GPP TR 36.889 V13.0.0, Study on licensed-assisted access to unlicensed spectrum (Release 13), Nov. 2015. |
| 42 | C. Dou et al., An analytical model for deriving receiver sensitivity and minimum transmit power in 802.11.6 wireless body area networks, in Proc. IEEE MTT-S Int. Microw. Workshop Series RF Wireless Technol. Biomed. Healthcare Applicat., Taipei, Sept. 21-23, 2015, pp. 138-140. |
| 43 | D. Haccoun and G. Begin, High-rate punctured convolutional codes for viterbi and sequential decoding, IEEE Trans. Commun. 37 (1989), no. 11, 1113-1125. DOI |
| 44 | J. Conan, The weight spectra of some short low-rate convolutional codes, IEEE Trans. Commun. 32 (1984), no. 9, 1050-1053. DOI |
| 45 | Y.S. Song and H.K. Choi, Analysis of V2V broadcast performance limit for WAVE communication systems using two-ray path loss model, ETRI J. 39 (2017), no. 2, 213-221. DOI |
 |
Korea Institute of Science and Technology Information
Gwahangno, Yuseong-gu, Daejeon, 305-806, Korea TEL : +82-42-869-1752
Copyright (c) 2009 KISTI. All Rights Reserved. For more information mail to
webmaster
