Abstract
To fully realize the potential of vehicular networks, several obstacles and challenges need to be addressed. Chief among the obstacles are strict QoS requirements of applications and differentiated service requirements in different situations. Although DSRC and WAVE have been adopted as the de facto standards, they do not address all the problems and there is room for improvements. In this study, we propose a generic prioritization and resource management algorithm that can be used to prioritize processing of received packets in vehicular networks. We formulate the generic severity-based prioritized packet processing problem as Penalized Multiple Knapsack Problem (PMKP) and prove that it is an NP-Hard problem. We thus develop a real-time heuristic that utilizes a relaxed version of the formulation. The relaxed formulation executes in polynomial time and guarantees a minimum delay per severity-level while respecting the processing rate constraint. To measure the performance of the proposed heuristic, real traffic data is used in a small-scale experiment. The proposed heuristic is tested against the PMKP solution and results show a small degradation of up to 4 percent in profit for the heuristic compared to the PMKP solution. Also, the proposed heuristic is tested against a non-prioritized processing algorithm that works using first come first served policy. Results show that the proposed heuristic gains 9 to 67 percent more profit than the non-prioritized processing algorithm in moderate and high congestion scenarios.
Highlights
1.1 MotivationDEDICATED short-range communications (DSRC) and Wireless Access in Vehicular Communications (WAVE) have become the de-facto vehicular communications technologies in VANETs
The proposed heuristic is tested against the Penalized Multiple Knapsack Problem (PMKP) solution and results show a small degradation of up to 4 percent in profit for the heuristic compared to the PMKP solution
Our study in this paper extends these special cases in the aforementioned sources to a more general prioritized processing of the received packets in VANETs, as a function of a generic severity metric, in order to maximize the overall profit to the system while respecting its Quality of Service (QoS) constraints
Summary
DEDICATED short-range communications (DSRC) and Wireless Access in Vehicular Communications (WAVE) have become the de-facto vehicular communications technologies in VANETs. IEEE 802.11p and IEEE P1609 form the bases of the WAVE protocol as shown in Fig. 1 [1]. To address the unique challenges in VANETs (i.e., dynamic topology, short communication periods and application requirements), WAVE uses multi-channel operations to increase channel utilization, and differentiated service categories to provide Quality of Service (QoS). To provide multi-channel operations, WAVE utilizes the IEEE 1609.4 standard, which defines six Service Channels (SCH) and one Control Channel (CCH) for use in VANETs [2]. These channels have different frequencies, maximum transmission power and applications. The CCH for instance is used for transmitting safety and control data in order to insure
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