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引用次数: 0
摘要
FlexRay 通信协议为车载通信网络中的硬截止日期和软截止日期流量提供了高带宽支持。在本文中,我们对 FlexRay 动态段处理的软截止日期流量进行了延迟分析。我们将这些信息的到达建模为泊松过程,并使用排队理论来评估它们所经历的平均延迟。最初,我们考虑了三个节点竞争服务的情况,假设三个节点中有两个可以在任何 FlexRay 周期中传输信息,并获得了相应队列的演化表达式。我们还确定了队列稳定的报文到达率范围。然后将这些结果扩展到 N 个队列的一般情况。分析结果与典型系统的模拟结果进行了比较。
Average delay analysis of soft deadline messages scheduled in the dynamic segment of FlexRay protocol
The FlexRay communication protocol provides high bandwidth for supporting both hard deadline and soft deadline traffic in in-vehicle communication networks. In this paper, we carry out delay analysis of soft deadline traffic which is handled by the dynamic segment of FlexRay. We model the arrival of these messages as Poisson processes, and use queuing theory to evaluate the average delay that they experience. Initially, we consider three nodes competing for service, assuming that two out of three can transmit messages in any FlexRay cycle and obtain expressions for the evolution of the corresponding queues. We also determine the range of message arrival rates for which the queues are stable. These results are then extended to the general case of N queues. The analytical results are compared with those obtained by simulation for a typical system.
期刊介绍:
Performance Evaluation functions as a leading journal in the area of modeling, measurement, and evaluation of performance aspects of computing and communication systems. As such, it aims to present a balanced and complete view of the entire Performance Evaluation profession. Hence, the journal is interested in papers that focus on one or more of the following dimensions:
-Define new performance evaluation tools, including measurement and monitoring tools as well as modeling and analytic techniques
-Provide new insights into the performance of computing and communication systems
-Introduce new application areas where performance evaluation tools can play an important role and creative new uses for performance evaluation tools.
More specifically, common application areas of interest include the performance of:
-Resource allocation and control methods and algorithms (e.g. routing and flow control in networks, bandwidth allocation, processor scheduling, memory management)
-System architecture, design and implementation
-Cognitive radio
-VANETs
-Social networks and media
-Energy efficient ICT
-Energy harvesting
-Data centers
-Data centric networks
-System reliability
-System tuning and capacity planning
-Wireless and sensor networks
-Autonomic and self-organizing systems
-Embedded systems
-Network science
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