An Energy Efficient Message Dissemination Scheme in Platoon-Based Driving Systems
Abstract
:1. Introduction
2. Related Works
3. Energy Efficient Message Dissemination
3.1. Arq-Based Relay Protocol
3.2. Adaptive Platoon Velocity Control Scheme
4. Mdp Formulation
4.1. State Space
- denotes the state of the platoon velocity, where is the maximum platoon velocity. All the velocities are normalized with respect to a unit platoon velocity, . Thus, the velocity of the platoon is considered to be an integer multiple of and can be defined as .
- is the set of driving modes of the platoon. The platoon takes the value 1 when it tries to accelerate the platoon velocity. On the contrary, the platoon takes the value 0 when it enters to the standby mode.
- is the state of the counter of the successful message dissemination, where C is a given threshold for the counter regarding consecutive successful message dissemination.
- is the set of time-slots in the duration of a frame for the operation of platoon-based driving. That is to say, is the union of two sets and , where is the set of slots in the duration of a section and is the driving operation time, in which the platoon changes its velocity after the finish of the message dissemination. There are totally M slots in a section; thus, the number of possible packet transmission attempt is M. In conclusion, a message dissemination is conducted in first M slot times of . After that, the change of the platoon velocity is performed in the th slot in .
- is the set of packet reception states, where P is the total number of possible combinations of cumulative status of ACK reception from every non-leader vehicles, i.e., , if there are totally vehicles in the platoon except the leader. Also, a possible case for the cumulative ACK reception is represented by a vector, which is represented by where is an index variable. That is, if ACK has been received from the the th follower vehicle within current slot, . Otherwise, . For example, if the total number of non-leader vehicle is 5 and the first and third follower vehicles have sent their ACKs until the current slot, . In addition, if .
- is the set of possible talkers, where total number of the vehicles in the platoon is N. Since talkers are vehicles who forward the control packets, tail is not included in the set of talkers.
4.2. Action Space
4.3. State Transition Function
4.4. Reward and Cost Functions
4.5. Optimal Equation
Algorithm 1: Value iteration algorithm. |
5. Performance Measures
6. Evaluation Results
6.1. Outage Probability
6.2. Average Velocity Level
6.3. Energy Efficiency
6.4. Effect of
7. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Kim, T.; Song, T.; Pack, S. An Energy Efficient Message Dissemination Scheme in Platoon-Based Driving Systems. Energies 2020, 13, 3940. https://doi.org/10.3390/en13153940
Kim T, Song T, Pack S. An Energy Efficient Message Dissemination Scheme in Platoon-Based Driving Systems. Energies. 2020; 13(15):3940. https://doi.org/10.3390/en13153940
Chicago/Turabian StyleKim, Taeyoon, Taewon Song, and Sangheon Pack. 2020. "An Energy Efficient Message Dissemination Scheme in Platoon-Based Driving Systems" Energies 13, no. 15: 3940. https://doi.org/10.3390/en13153940
APA StyleKim, T., Song, T., & Pack, S. (2020). An Energy Efficient Message Dissemination Scheme in Platoon-Based Driving Systems. Energies, 13(15), 3940. https://doi.org/10.3390/en13153940