Vehicular Ad Hoc Network (VANET) Connectivity Analysis of a Highway Toll Plaza
Abstract
:1. Introduction
2. Related Work
3. Analytical Model of Connectivity
3.1. System Model
- (1)
- Two vehicles are connected if the distance between them does not exceed the transmission range of a vehicle.
- (2)
- If any two vehicles on the sub-segment are connected, the sub-segment will be connected.
- (3)
- The two sub-segments connect if there are at least two vehicles that are connected on these two sub-segments.
- (4)
- The road is connected if at least two adjacent road segments are connected.
3.2. Connectivity Probability
- (1)
- D1: The location of the toll plaza is
- (2)
- D2: The location of the toll plaza is
- (3)
- D3: The location of the toll plaza is
- (4)
- D4: The location of the toll plaza is
- (1)
- D1.1: vehicles are traveling on segment;
- (2)
- D1.2: vehicles are not traveling on segment.
- (1)
- D1.1.1: vehicles are traveling on;
- (2)
- D1.1.2: vehicles are not traveling on.
- (1)
- D2.1: vehicles are traveling on;
- (2)
- D2.2: vehicles are not traveling on.
- (1)
- D2.1.1: vehicles are traveling on and ;
- (2)
- D2.1.2: vehicles are traveling on, but vehicles are not traveling on ;
- (3)
- D2.1.3: vehicles are not traveling on , but vehicles are traveling on
- (4)
- D2.1.4: vehicles are not traveling on either segment or .
- (1)
- D2.2.1: vehicles are traveling on but vehicles are not traveling on ;
- (2)
- D2.2.2: vehicles are not traveling on but vehicles are traveling on .
- (1)
- D3.1: vehicles are traveling on ;
- (2)
- D3.2: vehicles are not traveling on.
- (1)
- D3.1.1: vehicles are traveling on and ;
- (2)
- D3.1.2: vehicles are traveling on but not on ;
- (3)
- D3.1.3: vehicles are not traveling on but are on ;
- (4)
- D3.1.4: vehicles are not traveling on either segment or .
- (1)
- D3.2.1: vehicles are traveling on but not on
- (2)
- D3.2.2: vehicles are not traveling on but are on
- (1)
- D4.1: vehicles are traveling on ;
- (2)
- D4.2: vehicles are not traveling on .
- (1)
- D4.1.1: vehicles are traveling on and ;
- (2)
- D4.1.2: vehicles are traveling on but not on ;
- (3)
- D4.1.3: vehicles are not traveling on but are on ;
- (4)
- D4.1.4: vehicles are not traveling on or .
- (1)
- D4.2.1: vehicles are traveling on but are not on
- (2)
- D4.2.2: vehicles are not traveling on but are on
4. Experimental Results and Analysis
4.1. Adaptation of Proposed Model in a Realistic Scenario
4.2. Impacts of Various Parameters on Connectivity
5. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Symbol | Meaning |
---|---|
represents the probability of occurring event X. | |
represents the vehicle's availability on s segment of road. | |
represents the event that s segment of road is connected. | |
represents the unavailability of vehicles on s segment of road. | |
represents the s segment is not connected. | |
Suppose represents the event that segments and are connected, i.e., the two vehicles are connected that are traveling on segments and. |
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Hussain, S.; Wu, D.; Memon, S.; Bux, N.K. Vehicular Ad Hoc Network (VANET) Connectivity Analysis of a Highway Toll Plaza. Data 2019, 4, 28. https://doi.org/10.3390/data4010028
Hussain S, Wu D, Memon S, Bux NK. Vehicular Ad Hoc Network (VANET) Connectivity Analysis of a Highway Toll Plaza. Data. 2019; 4(1):28. https://doi.org/10.3390/data4010028
Chicago/Turabian StyleHussain, Saajid, Di Wu, Sheeba Memon, and Naadiya Khuda Bux. 2019. "Vehicular Ad Hoc Network (VANET) Connectivity Analysis of a Highway Toll Plaza" Data 4, no. 1: 28. https://doi.org/10.3390/data4010028
APA StyleHussain, S., Wu, D., Memon, S., & Bux, N. K. (2019). Vehicular Ad Hoc Network (VANET) Connectivity Analysis of a Highway Toll Plaza. Data, 4(1), 28. https://doi.org/10.3390/data4010028