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2014 | OriginalPaper | Buchkapitel

4. Downlink Capacity of Vehicular Networks with Access Infrastructure

verfasst von : Ning Lu, Xuemin (Sherman) Shen

Erschienen in: Capacity Analysis of Vehicular Communication Networks

Verlag: Springer New York

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Abstract

Wireless access infrastructure, such as Wi-Fi access points and cellular base stations, plays a vital role in offering pervasive Internet services to vehicles. However, the deployment costs of different access infrastructure are highly variable. In this chapter, we analyze the downlink capacity of vehicles and investigate the capacity-cost tradeoffs for the network in which access infrastructure is deployed to provide a downlink data pipe to all vehicles. Three alternatives of wireless access infrastructure are considered, i.e., cellular base stations (BSs), wireless mesh backbones (WMBs), and roadside access points (RAPs). We first derive a lower bound of downlink capacity for each type of access infrastructure. We then present a case study based on a ideal city grid of 400 km² with 0.4 million vehicles, in which we examine the capacity-cost tradeoffs for different deployment solutions in terms of both capital expenditures (CAPEX) and operational expenditures (OPEX). Rich implications from the results provide fundamental guidance on the choice of cost-effective wireless access infrastructure for the emerging vehicular networking.

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Vorheriges Kapitel Unicast Capacity of Vehicular Networks with Socialized Mobility

Nächstes Kapitel Conclusions and Future Directions

X is used to represent a ratio relationship rather that a specific value.

D. Jiang, V. Taliwal, A. Meier, W. Holfelder, R. Herrtwich, Design of 5.9 GHz DSRC-based vehicular safety communication. IEEE Wirel. Commun. 13(5), 36–43 (2006)

F. Martinez, C. Toh, J. Cano, C. Calafate, P. Manzoni, Emergency services in future intelligent transportation systems based on vehicular communication networks. IEEE Intell. Transp. Syst. Mag. 2(2), 6–20 (2010)

F. Bai, B. Krishnamachari, Exploiting the wisdom of the crowd: localized, distributed information-centric VANETs. IEEE Commun. Mag. 48(5), 138–146 (2010)

R. Lu, X. Lin, T. Luan, X. Liang, X. Shen, Pseudonym changing at social spots: an effective strategy for location privacy in VANETs. IEEE Trans. Veh. Technol. 61(1), 86–96 (2012)

N. Lu, N. Cheng, N. Zhang, X. Shen, J.W. Mark, VeMail: a message handling system towards efficient transportation management, in Proceedings of IEEE WCNC, Shanghai, Apr 2013

J. Lin, S. Chen, Y. Shih, S. Chen, A study on remote on-line diagnostic system for vehicles by integrating the technology of OBD, GPS, and 3G. World Acad. Sci. Eng. Technol. 56, 56 (2009)

M. Ramadan, M. Al-Khedher, S. Al-Kheder, Intelligent anti-theft and tracking system for automobiles. Int. J. Mach. Learn. Comput. 2(1), 88–92 (2012)

KPMG’s global automotive executive survey, [Online].Available: http://www.kpmg.com/GE/en/IssuesAndInsights/ArticlesPublications/Documents/Global-automotive-executive-survey-2012.pdf

B. Chen, M. Chan, Mobtorrent: a framework for mobile internet access from vehicles, in Proceedings of IEEE INFOCOM, Rio de Janeiro, Apr 2009

10.

T. Luan, X. Ling, X. Shen, MAC in motion: impact of mobility on the MAC of drive-thru internet. IEEE Trans. Mobile Comput. 11(2), 305–319 (2011)

11.

V. Bychkovsky, B. Hull, A. Miu, H. Balakrishnan, S. Madden, A measurement study of vehicular internet access using in situ wi-fi networks, in Proceedings of ACM MobiCom, Los Angeles, 2006

12.

A. Mahajan, N. Potnis, K. Gopalan, A. Wang, Modeling VANET deployment in urban settings, in Proceedings of ACM MSWiM, Chania, 2007, pp. 151–158

13.

T. Luan, L. Cai, J. Chen, X. Shen, F. Bai, VTube: towards the media rich city life with autonomous vehicular content distribution, in Proceedings of IEEE SECON, Salt Lake City, June 2011

14.

G. Karagiannis, O. Altintas, E. Ekici, G. Heijenk, B. Jarupan, K. Lin, T. Weil, Vehicular networking: a survey and tutorial on requirements, architectures, challenges, standards and solutions. IEEE Commun. Surv. Tutor. 13(4), 1–33 (2011)

15.

J. Kenney, Dedicated short-range communications (DSRC) standards in the united states. Proc. IEEE 99(7), 1162–1182 (2011)

16.

H. Hartenstein, K. Laberteaux, I. Ebrary, VANET: Vehicular Applications and Inter-networking Technologies (Wiley Online Library, Chichester, 2010)

17.

H. Hartenstein, K. Laberteaux, A tutorial survey on vehicular ad hoc networks. IEEE Commun. Mag. 46(6), 164–171 (2008)

18.

A. El Gamal, Y. Kim, Network Information Theory (Cambridge University Press, Cambridge/New York, 2011)MATH

19.

J. Andrews, S. Shakkottai, R. Heath, N. Jindal, M. Haenggi, R. Berry, D. Guo, M. Neely, S. Weber, S. Jafar et al., Rethinking information theory for mobile ad hoc networks. IEEE Commun. Mag. 46(12), 94–101 (2008)

20.

C. Shannon, A mathematical theory of communication. ACM SIGMOBILE Mobile Comput. Commun. Rev. 5(1), 3–55 (2001)

21.

T. Cover, A. Gamal, Capacity theorems for the relay channel. IEEE Trans. Inf. Theory 25(5), 572–584 (1979)MATH

22.

P. Gupta, P. Kumar, The capacity of wireless networks. IEEE Trans. Inf. Theory 46(2), 388–404 (2000)MathSciNetMATH

23.

A. Goldsmith, M. Effros, R. Koetter, M. Médard, A. Ozdaglar, L. Zheng, Beyond shannon: the quest for fundamental performance limits of wireless ad hoc networks. IEEE Commun. Mag. 49(5), 195–205 (2011)

24.

P. Li, M. Pan, Y. Fang, The capacity of three-dimensional wireless ad hoc networks, in Proceedings of IEEE INFOCOM, Shanghai, Apr 2011

25.

H. Pishro-Nik, A. Ganz, D. Ni, The capacity of vehicular ad hoc networks, in Proceedings of Allerton Conference, University of Illinois at Urbana-Champaign, Monticello, Illinois, USA 2007

26.

M. Nekoui, A. Eslami, H. Pishro-Nik, Scaling laws for distance limited communications in vehicular ad hoc networks, in Proceedings of IEEE ICC, Beijing, 2008, pp. 2253–2257

27.

G. Zhang, Y. Xu, X. Wang, X. Tian, J. Liu, X. Gan, H. Yu, L. Qian, Multicast capacity for hybrid VANETs with directional antenna and delay constraint. IEEE J. Sel. Areas Commun. 30(4), 818–833 (2012)

28.

M. Wang, H. Shan, L. Cai, N. Lu, X. Shen, F. Bai, Throughput capacity of VANETs by exploiting mobility diversity, in Proceedings of IEEE ICC, Ottawa, June 2012

29.

N. Lu, T. Luan, M. Wang, X. Shen, F. Bai, Bounds of asymptotic performance limits of social-proximity vehicular networks. IEEE/ACM Trans. Netw. to appear

30.

N. Lu, N. Zhang, N. Cheng, X. Shen, J.W. Mark, F. Bai, Vehicles meet infrastructure: towards capacity-cost tradeoffs for vehicular access networks. IEEE Trans. Intell. Transp. Syst. to appear

31.

T. Cover, J. Thomas, J. Wiley et al., Elements of Information Theory, vol. 306 (Wiley Online Library, John Wiley & Sons, Inc., Hoboken, New Jersey 1991)

32.

M. Franceschetti, O. Dousse, D. Tse, P. Thiran, Closing the gap in the capacity of wireless networks via percolation theory. IEEE Trans. Inf. Theory 53(3), 1009–1018 (2007)MathSciNet

33.

S. Yi, Y. Pei, S. Kalyanaraman, On the capacity improvement of ad hoc wireless networks using directional antennas, in Proceedings of ACM MobiHoc, Annapolis, 2003

34.

C. Peraki, S. Servetto, On the maximum stable throughput problem in random networks with directional antennas, in Proceedings of ACM MobiHoc, Annapolis, 2003

35.

H. Sadjadpour, Z. Wang, J. Garcia-Luna-Aceves, The capacity of wireless ad hoc networks with multi-packet reception. IEEE Trans. Commun. 58(2), 600–610 (2010)

36.

J. Garcia-Luna-Aceves, H. Sadjadpour, Z. Wang, Challenges: towards truly scalable ad hoc networks, in Proceedings of ACM MobiCom, Montreal, 2007

37.

Z. Wang, H. Sadjadpour, J. Garcia-Luna-Aceves, The capacity and energy efficiency of wireless ad hoc networks with multi-packet reception, in Proceedings of MobiHoc, Hong Kong. (ACM, 2008), pp. 179–188

38.

Z. Wang, H. Sadjadpour, J. Garcia-Luna-Aceves, Fundamental limits of information dissemination in wireless ad hoc networks–part II: multi-packet reception. IEEE Trans. Wirel. Commun. 10(3), 803–813 (2011)

39.

S. Aeron, V. Saligrama, Wireless ad hoc networks: strategies and scaling laws for the fixed SNR regime. IEEE Trans. Inf. Theory 53(6), 2044–2059 (2007)MathSciNet

40.

A. Ozgur, O. Lévêque, D. Tse, Hierarchical cooperation achieves optimal capacity scaling in ad hoc networks. IEEE Trans. Inf. Theory 53(10), 3549–3572 (2007)

41.

J. Ghaderi, L. Xie, X. Shen, Hierarchical cooperation in ad hoc networks: optimal clustering and achievable throughput. IEEE Trans. Inf. Theory 55(8), 3425–3436 (2009)MathSciNet

42.

U. Niesen, P. Gupta, D. Shah, On capacity scaling in arbitrary wireless networks. IEEE Trans. Inf. Theory 55(9), 3959–3982 (2009)MathSciNet

43.

M. Franceschetti, M. Migliore, P. Minero, The capacity of wireless networks: information-theoretic and physical limits. IEEE Trans. Inf. Theory 55(8), 3413–3424 (2009)MathSciNet

44.

S. Lee, S. Chung, Capacity scaling of wireless ad hoc networks: Shannon meets Maxwell. IEEE Trans. Inf. Theory 58(3), 1702–1715 (2012)MathSciNet

45.

K. Lu, S. Fu, Y. Qian, H. Chen, On capacity of random wireless networks with physical-layer network coding. IEEE J. Sel. Areas Commun. 27(5), 763–772 (2009)

46.

J. Liu, D. Goeckel, D. Towsley, The throughput order of ad hoc networks employing network coding and broadcasting, in IEEE Proceedings of MILCOM, Washington, DC, Oct 2006

47.

J. Liu, D. Goeckel, D. Towsley, Bounds on the gain of network coding and broadcasting in wireless networks, in IEEE Proceedings of INFOCOM, Anchorage, May 2007

48.

A. Keshavarz-Haddadt, R. Riedi, Bounds on the benefit of network coding: throughput and energy saving in wireless networks, in IEEE Proceedings of INFOCOM, Phoenix, Mar 2008

49.

J. Liu, D. Goeckel, D. Towsley, Bounds on the throughput gain of network coding in unicast and multicast wireless networks. IEEE J. Sel. Areas Commun. 27(5), 582–592 (2009)

50.

R. Negi, A. Rajeswaran, Capacity of power constrained ad-hoc networks, in IEEE Proceedings of INFOCOM, Hong Kong, Mar 2004

51.

X. Tang, Y. Hua, Capacity of ultra-wideband power-constrained ad hoc networks. IEEE Trans. Inf. Theory 54(2), 916–920 (2008)MathSciNet

52.

H. Zhang, J. Hou, Capacity of wireless ad-hoc networks under ultra wide band with power constraint, in IEEE Proceedings of INFOCOM, Miami, Mar 2005

53.

M. Grossglauser, D. Tse, Mobility increases the capacity of ad hoc wireless networks. IEEE/ACM Trans. Netw. 10(4), 477–486 (2002)

54.

S. Diggavi, M. Grossglauser, D. Tse, Even one-dimensional mobility increases the capacity of wireless networks. IEEE Trans. Inf. Theory 51(11), 3947–3954 (2005)MathSciNet

55.

S. Jafar, Too much mobility limits the capacity of wireless ad hoc networks. IEEE Trans. Inf. Theory 51(11), 3954–3965 (2005)MathSciNet

56.

P. Kyasanur, N. Vaidya, Capacity of multi-channel wireless networks: impact of number of channels and interfaces, in Proceedings of ACM MobiCom, Cologne, 2005

57.

P. Kyasanur, N. Vaidya, Capacity of multichannel wireless networks under the protocol model. IEEE/ACM Trans. Netw. 17(2), 515–527 (2009)

58.

M. Kodialam, T. Nandagopal, Characterizing the capacity region in multi-radio multi-channel wireless mesh networks, in Proceedings of ACM MobiCom, Cologne, 2005

59.

S. Toumpis, A. Goldsmith, Large wireless networks under fading, mobility, and delay constraints, in Proceeding of IEEE INFOCOM, Hongkong, Mar 2004

60.

M. Ebrahimi, M. Maddah-Ali, A. Khandani, Throughput scaling laws for wireless networks with fading channels. IEEE Trans. Inf. Theory 53(11), 4250–4254 (2007)MathSciNet

61.

R. Gowaikar, B. Hochwald, B. Hassibi, Communication over a wireless network with random connections. IEEE Trans. Inf. Theory 52(7), 2857–2871 (2006)MathSciNet

62.

S. Cui, A. Haimovich, O. Somekh, H. Poor, S. Shamai, Throughput scaling of wireless networks with random connections. IEEE Trans. Inf. Theory 56(8), 3793–3806 (2010)MathSciNet

63.

R. Gowaikar, B. Hassibi, Achievable throughput in two-scale wireless networks. IEEE J. Sel. Areas Commun. 27(7), 1169–1179 (2009)

64.

R. Jaber, J. Andrews, A lower bound on the capacity of wireless erasure networks. IEEE Trans. Inf. Theory 57(10), 6502–6513 (2011)MathSciNet

65.

C. Hu, X. Wang, Z. Yang, J. Zhang, Y. Xu, X. Gao, A geometry study on the capacity of wireless networks via percolation. IEEE Trans. Commun. 58(10), 2916–2925 (2010)

66.

P. Li, M. Pan, Y. Fang, Capacity bounds of three-dimensional wireless ad hoc networks. IEEE/ACM Trans. Netw. 20(4), 1304–1315 (2012)

67.

A. Keshavarz-Haddad, V. Ribeiro, R. Riedi, Broadcast capacity in multihop wireless networks, in Proceedings of ACM MobiCom, Los Angeles, 2006

68.

R. Zheng, Asymptotic bounds of information dissemination in power-constrained wireless networks. IEEE Trans. Wirel. Commun. 7(1), 251–259 (2008)

69.

X. Li, J. Zhao, Y. Wu, S. Tang, X. Xu, X. Mao, Broadcast capacity for wireless ad hoc networks, in Proceedings of IEEE MASS, Atlanta, Sept 2008

70.

S. Li, Y. Liu, X. Li, Capacity of large scale wireless networks under gaussian channel model, in Proceedings of ACM MobiCom, San Francisco, 2008

71.

X. Li, Multicast capacity of wireless ad hoc networks. IEEE/ACM Trans. Netw. 17(3), 950–961 (2009)

72.

C. Wang, X. Li, C. Jiang, S. Tang, Y. Liu, J. Zhao, Scaling laws on multicast capacity of large scale wireless networks, in Proceedings of IEEE INFOCOM, Rio de Janeiro, Apr 2009

73.

S. Shakkottai, X. Liu, R. Srikant, The multicast capacity of large multihop wireless networks. IEEE/ACM Trans. Netw. 18(6), 1691–1700 (2010)

74.

U. Niesen, P. Gupta, D. Shah, The balanced unicast and multicast capacity regions of large wireless networks. IEEE Trans. Inf. Theory 56(5), 2249–2271 (2010)MathSciNet

75.

X. Wang, W. Huang, S. Wang, J. Zhang, C. Hu, Delay and capacity tradeoff analysis for motioncast. IEEE/ACM Trans. Netw. 19(5), 1354–1367 (2011)

76.

X. Wang, L. Fu, C. Hu, Multicast performance with hierarchical cooperation. IEEE/ACM Trans. Netw. 20(3), 917–930 (2012)

77.

D. Nie, A survey on multicast capacity of wireless ad hoc networks (2009). [Online]. Available: http://iwct.sjtu.edu.cn/personal/xwang8/research/nieding/survey.pdf

78.

Z. Wang, H. Sadjadpour, J. Garcia-Luna-Aceves, A unifying perspective on the capacity of wireless ad hoc networks, in Proceedings of IEEE INFOCOM, Phoenix, Apr 2008

79.

G. Sharma, R. Mazumdar, N. Shroff, Delay and capacity trade-offs in mobile ad hoc networks: a global perspective. IEEE/ACM Trans. Netw. 15(5), 981–992 (2007)

80.

D. Ciullo, V. Martina, M. Garetto, E. Leonardi, Impact of correlated mobility on delay-throughput performance in mobile ad-hoc networks, in Proceedings of IEEE INFOCOM, San Diego, Mar 2010

81.

S. Ross, Introduction to Probability Models (Academic, Academic Press, Burlington, MA, USA 2009)

82.

K. Lee, Y. Kim, S. Chong, I. Rhee, Y. Yi, Delay-capacity tradeoffs for mobile networks with Lévy walks and Lévy flights, in Proceedings of IEEE INFOCOM, San Diego, Mar 2010

83.

I. Rhee, M. Shin, S. Hong, K. Lee, S. Kim, S. Chong, On the Levy-walk nature of human mobility. IEEE/ACM Trans. Netw. 19(3), 630–643 (2011)

84.

M. Neely, E. Modiano, Capacity and delay tradeoffs for ad hoc mobile networks. IEEE Trans. Inf. Theory 51(6), 1917–1937 (2005)MathSciNet

85.

L. Ying, S. Yang, R. Srikant, Optimal delay–throughput tradeoffs in mobile ad hoc networks. IEEE Trans. Inf. Theory 54(9), 4119–4143 (2008)MathSciNet

86.

X. Lin, N. Shroff, The fundamental capacity-delay tradeoff in large mobile ad hoc networks, in Proceedings of 3rd Annual Mediterranean Ad Hoc Networking Workshop, Bodrum, June 2004

87.

A. El Gamal, J. Mammen, B. Prabhakar, D. Shah, Optimal throughput-delay scaling in wireless networks-part I: the fluid model. IEEE Trans. Inf. Theory 52(6), 2568–2592 (2006)

88.

X. Lin, G. Sharma, R. Mazumdar, N. Shroff, Degenerate delay-capacity tradeoffs in ad-hoc networks with brownian mobility. IEEE Trans. Inf. Theory 52(6), 2777–2784 (2006)MathSciNet

89.

G. Sharma, R. Mazumdar, Scaling laws for capacity and delay in wireless ad hoc networks with random mobility, in Proceedings of IEEE ICC, Paris, June 2004

90.

P. Li, Y. Fang, J. Li, Throughput, delay, and mobility in wireless ad hoc networks, in Proceedings of IEEE INFOCOM, San Diego, Mar 2010

91.

M. Garetto, P. Giaccone, E. Leonardi, On the capacity of ad hoc wireless networks under general node mobility, in Proceedings of IEEE INFOCOM, Anchorage, May 2007

92.

M. Garetto, P. Giaccone, E. Leonardi, Capacity scaling of sparse mobile ad hoc networks, in Proceedings of IEEE INFOCOM, Phoenix, Apr 2008

93.

M. Garetto, P. Giaccone, E. Leonardi, Capacity scaling in ad hoc networks with heterogeneous mobile nodes: the super-critical regime. IEEE/ACM Trans. Netw. 17(5), 1522–1535 (2009)

94.

M. Garetto, P. Giaccone, E. Leonardi, Capacity scaling in ad hoc networks with heterogeneous mobile nodes: the subcritical regime. IEEE/ACM Trans. Netw. 17(6), 1888–1901 (2009)

95.

M. Garetto, E. Leonardi, Restricted mobility improves delay-throughput tradeoffs in mobile ad hoc networks. IEEE Trans. Inf. Theory 56(10), 5016–5029 (2010)MathSciNet

96.

A. Ozgur, O. Lévêque, Throughput-delay tradeoff for hierarchical cooperation in ad hoc wireless networks. IEEE Trans. Inf. Theory 56(3), 1369–1377 (2010)

97.

C. Comaniciu, H. Poor, On the capacity of mobile ad hoc networks with delay constraints. IEEE Trans. Wirel. Commun. 5(8), 2061–2071 (2006)

98.

B. Liu, Z. Liu, D. Towsley, On the capacity of hybrid wireless networks, in Proceedings of IEEE INFOCOM, San Francisco, Mar 2003

99.

U. Kozat, L. Tassiulas, Throughput capacity of random ad hoc networks with infrastructure support, in Proceedings of ACM MobiCom, San Diego, 2003, pp. 55–65

100.

S. Toumpis, Capacity bounds for three classes of wireless networks: asymmetric, cluster, and hybrid, in Proceedings of ACM MobiHoc, Tokyo, 2004, pp. 133–144

101.

A. Zemlianov, G. De Veciana, Capacity of ad hoc wireless networks with infrastructure support. IEEE J. Sel. Areas Commun. 23(3), 657–667 (2005)

102.

B. Liu, P. Thiran, D. Towsley, Capacity of a wireless ad hoc network with infrastructure, in Proceedings of the 8th ACM International Symposium on mobile Ad Hoc Networking and Computing, Montréal (ACM, 2007), pp. 239–246

103.

P. Li, Y. Fang, Impacts of topology and traffic pattern on capacity of hybrid wireless networks. IEEE Trans. Mobile Comput. 8(12), 1585–1595 (2009)

104.

D. Shila, Y. Cheng, T. Anjali, Throughput and delay analysis of hybrid wireless networks with multi-hop uplinks, in Proceedings of IEEE INFOCOM, Shanghai, Apr 2011

105.

P. Li, C. Zhang, Y. Fang, Capacity and delay of hybrid wireless broadband access networks. IEEE J. Sel. Areas Commun. 27(2), 117–125 (2009)

106.

G. Zhang, Y. Xu, X. Wang, M. Guizani, Capacity of hybrid wireless networks with directional antenna and delay constraint. IEEE Trans. Commun. 58(7), 2097–2106 (2010)

107.

W. Shin, S. Jeon, N. Devroye, M. Vu, S. Chung, Y. Lee, V. Tarokh, Improved capacity scaling in wireless networks with infrastructure. IEEE Trans. Inf. Theory 57(8), 5088–5102 (2011)MathSciNet

108.

W. Huang, X. Wang, Q. Zhang, Capacity scaling in mobile wireless ad hoc network with infrastructure support, in Proceedings of IEEE ICDCS, Genoa, June 2010

109.

P. Li, Y. Fang, The capacity of heterogeneous wireless networks, in Proceedings of IEEE INFOCOM, San Diego, Mar 2010

110.

P. Zhou, X. Wang, R. Rao, Asymptotic capacity of infrastructure wireless mesh networks. IEEE Trans. Mobile Comput. 7(8), 1011–1024 (2008)

111.

L. Law, K. Pelechrinis, S. Krishnamurthy, M. Faloutsos, Downlink capacity of hybrid cellular ad hoc networks. IEEE/ACM Trans. Netw. 18(1), 243–256 (2010)

112.

P. Li, X. Huang, Y. Fang, Capacity scaling of multihop cellular networks, in Proceedings of IEEE INFOCOM, Shanghai, Apr 2011

113.

N. Zhang, N. Lu, R. Lu, J.W. Mark, X. Shen, Energy-efficient and trust-aware cooperation in cognitive radio networks, in Proceedings of IEEE ICC, Ottawa, June 2012

114.

M. Vu, V. Tarokh, Scaling laws of single-hop cognitive networks. IEEE Trans. Wirel. Commun. 8(8), 4089–4097 (2009)

115.

S. Jeon, N. Devroye, M. Vu, S. Chung, V. Tarokh, Cognitive networks achieve throughput scaling of a homogeneous network. IEEE Trans. Inf. Theory 57(8), 5103–5115 (2011)MathSciNet

116.

C. Yin, L. Gao, S. Cui, Scaling laws for overlaid wireless networks: a cognitive radio network versus a primary network. IEEE/ACM Trans. Netw. 18(4), 1317–1329 (2010)

117.

W. Huang, X. Wang, Capacity scaling of general cognitive networks. IEEE/ACM Trans. Netw. to appear

118.

Y. Li, X. Wang, X. Tian, X. Liu, Scaling laws for cognitive radio network with heterogeneous mobile secondary users, in Proceedings of IEEE INFOCOM, Orlando, Mar 2012

119.

N. Sarafijanovic-Djukic, M. Pidrkowski, M. Grossglauser, Island hopping: efficient mobility-assisted forwarding in partitioned networks, in Proceedings of IEEE SECON, Reston, Sept 2006

120.

S. Kostof, R. Tobias, The City Shaped (Thames and Hudson, London, 1991)

121.

A. Siksna, The effects of block size and form in North American and Australian city centres. Urban Morphol. 1, 19–33 (1997)

122.

M. Neely, E. Modiano, C. Rohrs, Dynamic power allocation and routing for time-varying wireless networks. IEEE J. Sel. Areas Commun. 23(1), 89–103 (2005)

123.

R. Urgaonkar, M. Neely, Network capacity region and minimum energy function for a delay-tolerant mobile ad hoc network. IEEE/ACM Trans. Netw. 19(4), 1137–1150 (2011)

124.

D. Slaughter, Difference Equations to Differential Equations (University Press of Florida, Gainesville, FL, USA 2009)

125.

R. Motwani, P. Raghavan, Randomized Algorithms (Chapman & Hall/CRC, Cambridge University Press, Cambridge, UK 1995)MATH

126.

V. Vapnik, A. Chervonenkis, On the uniform convergence of relative frequencies of events to their probabilities. Theory Probab. Appl. 16, 264 (1971)MATH

127.

V. Vapnik, Statistical Learning Theory (Wiley-Interscience, New York, 1998)MATH

128.

N. Banerjee, M. Corner, D. Towsley, B. Levine, Relays, base stations, and meshes: enhancing mobile networks with infrastructure, in Proceedings of ACM MobiCom, San Francisco, 2008

129.

J. Eriksson, H. Balakrishnan, S. Madden, Cabernet: vehicular content delivery using WiFi, in Proceedings of ACM MobiCom, San Francisco, 2008

130.

F. Malandrino, C. Casetti, C.-F. Chiasserini, M. Fiore, Content downloading in vehicular networks: what really matters, in Proceedings of IEEE INFOCOM, Shanghai, Apr 2011

131.

C. Stefanović, D. Vukobratović, F. Chiti, L. Niccolai, V. Crnojević, R. Fantacci, Urban infrastructure-to-vehicle traffic data dissemination using uep rateless codes. IEEE J. Sel. Areas Commun. 29(1), 94–102 (2011)

132.

I.W.-H. Ho, K.K. Leung, J.W. Polak, Stochastic model and connectivity dynamics for vanets in signalized road systems. IEEE/ACM Trans. Netw. 19(1), 195–208 (2011)

133.

H. Xia, A simplified analytical model for predicting path loss in urban and suburban environments. IEEE Trans. Veh. Technol. 46(4), 1040–1046 (1997)

134.

J. Lee, R. Mazumdar, N. Shroff, Joint resource allocation and base-station assignment for the downlink in CDMA networks. IEEE/ACM Trans. Netw. 14(1), 1–14 (2006)

135.

F. Baccelli, B. Blaszczyszyn, Stochastic Geometry and Wireless Networks Volume I: Theory. Foundations and Trends in Networking (NOW, Now Publishers, Hanover 2010)

136.

F. Baccelli, B. Blaszczyszyn, Stochastic Geometry and Wireless Networks Volume II: Applications. Foundations and Trends in Networking (NOW, Now Publishers, Hanover 2010)

137.

M. Haenggi, R. Ganti, Interference in Large Wireless Networks (Now Publishers, Hanover, 2009)

138.

K. Johansson, Cost effective deployment strategies for heterogeneous wireless networks. Ph.D. Dissertation, Kommunikationsteknik, Kungliga Tekniska högskolan, 2007

139.

C. Wang, C. Jiang, X. Li, S. Tang, P. Yang, General capacity scaling of wireless networks, in Proceedings of IEEE INFOCOM, Shanghai, Apr 2011

140.

C. Jiang, Y. Shi, Y. Hou, W. Lou, S. Kompella, S. Midkiff, Toward simple criteria to establish capacity scaling laws for wireless networks, in Proceedings IEEE INFOCOM, 2012, Orlando (IEEE, 2012), pp. 774–782

141.

S. Weber, X. Yang, J. Andrews, G. De Veciana, Transmission capacity of wireless ad hoc networks with outage constraints. IEEE Trans. Inf. Theory 51(12), 4091–4102 (2005)

142.

A. Hunter, J. Andrews, S. Weber, Transmission capacity of ad hoc networks with spatial diversity. IEEE Trans. Wirel. Commun. 7(12), 5058–5071 (2008)

143.

S. Weber, J. Andrews, N. Jindal, An overview of the transmission capacity of wireless networks. IEEE Trans. Commun. 58(12), 3593–3604 (2010)

Titel: Downlink Capacity of Vehicular Networks with Access Infrastructure
verfasst von: Ning Lu
Xuemin (Sherman) Shen
Verlag: Springer New York
Buch: Capacity Analysis of Vehicular Communication Networks
Print ISBN: 978-1-4614-8396-0

Electronic ISBN: 978-1-4614-8397-7

Copyright-Jahr: 2014
DOI: https://doi.org/10.1007/978-1-4614-8397-7_4

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