Presentation is loading. Please wait.

Presentation is loading. Please wait.

Analytical Model for Connectivity in Vehicular Ad Hoc Networks Published in IEEE TVT vol. 57, no. 6, November 2008 Authors: Saleh Yousefi, Eitan Altman,

Published byWarren Watson Modified over 8 years ago

Similar presentations

Presentation on theme: "Analytical Model for Connectivity in Vehicular Ad Hoc Networks Published in IEEE TVT vol. 57, no. 6, November 2008 Authors: Saleh Yousefi, Eitan Altman,"— Presentation transcript:

1 Analytical Model for Connectivity in Vehicular Ad Hoc Networks Published in IEEE TVT vol. 57, no. 6, November 2008 Authors: Saleh Yousefi, Eitan Altman, Rachid El-Azouzi, Mahmood Fathy (INRIA, Sophia Antipolis, France) Presenter: Hojin Lee

2 Connectivity Cluster Platoon size –The number of vehicles in each spatial connected cluster –How many vehicles can hear or exchange data Information sharing … Connectivity distance –The length of the connected path –How far are packets delivered by wireless multi-hop (forwarding) Announcement area Accessibility to roadside equipment (e.g., Internet gateway) …

3 Factors for connectivity Traffic pattern –Traffic flow –Average speed –Density –… –Cf> Traffic flow = average speed x density

4 Assumptions Vehicles arrival follows a Poisson process –Poisson process? N discrete levels of constant speed –This assumption will be relaxed to truncated Gaussian distribution

5 Basic Idea M/D/∞ queueing system –Queueing system? Arrival Service queued –Borrow the concept of busy period Shift from time domain to space domain –Inter-arrival time  inter-vehicle distance –Service time  transmission range –Busy period length  connectivity distance

6 Inter-vehicle distance (1/3) Arrival rate of cars with speed v i : λ i –Poisson process (assumption) Total arrival rate: λ = ∑ i λ i –Poisson process (merging) Occurrence probability of cars with speed v i – P i = λ i /λ

7 Inter-vehicle distance (2/3) Inter-vehicle distance between cars with speed v i –Inter-arrival time sequence of cars with speed v i (T n i :=t n i - t n-1 i ) Exponentially distributed with a parameter λ i –E[T i ]=1/λ i –Inter-vehicle distance sequence of cars with speed v i S n i := T n i v i E[S i ]= v i /λ i –Exponentially distributed with a parameter λ i /v i = λ P i /v i

8 Inter-vehicle distance (3/3) Poisson distribution: merge and split Inter-vehicle distance between any cars –Inter-arrival time: exponential distribution ≡ the number of arrival: Poisson distribution –Merging inter-vehicle distance of cars with speed v i Exponentially distributed with a parameter λ L = ∑ i λ i /v i = λ∑ i P i /v i –CDF: F L (x)=Pr(L<x)=1-exp(-λ L x) –Pr(L>x)=exp(-λ L x)

9 Speed levels (1/2) The speeds in the free-flow traffic: normally distributed – –μ: the average speed, σ: the standard deviation

10 Speed levels (2/2) Use a truncated version –to avoid dealing with negative speeds or even getting close to zero speed –v min, v max (μ -3σ, μ + 3σ) – about 99.7% of the whole area – where v min < v < v max, and

11 Queueing system Inter-arrival time distribution –Inter-vehicle distance: exponential distribution with a parameter λ d Service time distribution –Transmission range: deterministic R The number of queues –∞ M/D/∞ queueing system

12 Platoon Size The number of customers served during busy period  platoon size Probability generating function of – – PMF of platoon size – Expectation of platoon size –

13 Connectivity distance Pdf of busy period  pdf of connectivity distance d: random variable for connectivity distance f d (s) = Laplace transform (moment generating function) of the pdf – Expectation of connectivity distance –

14 Conclusions and Future directions Busy period in Queueing system –Time domain  space domain –This framework is easily adaptable for other fields Also consider speed levels –But, in free-flow traffic state (normal distribution - independence) –Not for car-following model Platoon size –Shared data storage like p2p –Unit of DTN routing Platoon size/connectivity length –Could be used as the congestion metric Forwarding or carrying –Performance Evaluation of a DTN as a City-wide Infrastructure Network - CFI '09 –Delay Bounded Routing in Vehicular Ad-hoc Networks – ACM MobiHoc ‘08

15 Appendix

16 Distributions (1/2) Bernoulli trial –Success/failure Binomial distribution  Poisson distribution –Independent event (arrival) –Success rate  arrival rate –Discrete time  continuous time Geometric distribution  Exponential distribution

17 Distributions (2/2) Normal distribution –PDF: –CDF (standard):

18 Poisson XXX Poisson distribution Poisson process Stochastic process Markov process

19 Generating function Probability generating function – – The PMF of X is recovered by taking derivatives of G – The expectation of X is given by Moment generating function ((Laplace) transform) –

Download ppt "Analytical Model for Connectivity in Vehicular Ad Hoc Networks Published in IEEE TVT vol. 57, no. 6, November 2008 Authors: Saleh Yousefi, Eitan Altman,"

Similar presentations

Traffic and routing. Network Queueing Model Packets are buffered in egress queues waiting for serialization on line Link capacity is C bps Average packet.

Traffic and routing. Network Queueing Model Packets are buffered in egress queues waiting for serialization on line Link capacity is C bps Average packet.
Many useful applications, especially in queueing systems, inventory management, and reliability analysis. A connection between discrete time Markov chains.

Many useful applications, especially in queueing systems, inventory management, and reliability analysis. A connection between discrete time Markov chains.
Discrete Uniform Distribution

Discrete Uniform Distribution
Queuing Network Models for Delay Analysis of Multihop Wireless Ad Hoc Networks Nabhendra Bisnik and Alhussein Abouzeid Rensselaer Polytechnic Institute.

Queuing Network Models for Delay Analysis of Multihop Wireless Ad Hoc Networks Nabhendra Bisnik and Alhussein Abouzeid Rensselaer Polytechnic Institute.
Delay and Throughput in Random Access Wireless Mesh Networks Nabhendra Bisnik, Alhussein Abouzeid ECSE Department Rensselaer Polytechnic Institute (RPI)

Delay and Throughput in Random Access Wireless Mesh Networks Nabhendra Bisnik, Alhussein Abouzeid ECSE Department Rensselaer Polytechnic Institute (RPI)
Random Variable A random variable X is a function that assign a real number, X(ζ), to each outcome ζ in the sample space of a random experiment. Domain.

Random Variable A random variable X is a function that assign a real number, X(ζ), to each outcome ζ in the sample space of a random experiment. Domain.
Queueing Model 2004. 5. 29 박희경.

Queueing Model 박희경.
Queuing Analysis Based on noted from Appendix A of Stallings Operating System text 6/10/20151.

Queuing Analysis Based on noted from Appendix A of Stallings Operating System text 6/10/20151.
TDC 369 / TDC 432 April 2, 2003 Greg Brewster. Topics Math Review Probability –Distributions –Random Variables –Expected Values.

TDC 369 / TDC 432 April 2, 2003 Greg Brewster. Topics Math Review Probability –Distributions –Random Variables –Expected Values.
1 Review of Probability Theory [Source: Stanford University]

1 Review of Probability Theory [Source: Stanford University]
1 Performance Evaluation of Computer Networks Objectives  Introduction to Queuing Theory  Little’s Theorem  Standard Notation of Queuing Systems  Poisson.

1 Performance Evaluation of Computer Networks Objectives  Introduction to Queuing Theory  Little’s Theorem  Standard Notation of Queuing Systems  Poisson.
Queuing and Transportation

Queuing and Transportation
A random variable that has the following pmf is said to be a binomial random variable with parameters n, p The Binomial random variable.

A random variable that has the following pmf is said to be a binomial random variable with parameters n, p The Binomial random variable.
Queuing Analysis Based on noted from Appendix A of Stallings Operating System text 6/28/20151.

Queuing Analysis Based on noted from Appendix A of Stallings Operating System text 6/28/20151.
2. Random variables  Introduction  Distribution of a random variable  Distribution function properties  Discrete random variables  Point mass  Discrete.

2. Random variables  Introduction  Distribution of a random variable  Distribution function properties  Discrete random variables  Point mass  Discrete.
The moment generating function of random variable X is given by Moment generating function.

The moment generating function of random variable X is given by Moment generating function.
7/3/2015© 2007 Raymond P. Jefferis III1 Queuing Systems.

7/3/2015© 2007 Raymond P. Jefferis III1 Queuing Systems.
BCOR 1020 Business Statistics Lecture 11 – February 21, 2008.

BCOR 1020 Business Statistics Lecture 11 – February 21, 2008.
Discrete Random Variables and Probability Distributions

Discrete Random Variables and Probability Distributions
Chapter 21 Random Variables Discrete: Bernoulli, Binomial, Geometric, Poisson Continuous: Uniform, Exponential, Gamma, Normal Expectation & Variance, Joint.

Chapter 21 Random Variables Discrete: Bernoulli, Binomial, Geometric, Poisson Continuous: Uniform, Exponential, Gamma, Normal Expectation & Variance, Joint.

Similar presentations

Ads by Google