Lifetime of motes in wireless sensor networks can be enlarged by decreasing the energy spent for communication. Approaches like time slotted channel hopping pursue this goal by performing frame exchanges according to a predefined schedule, which helps reducing the duty cycle. Unfortunately, whenever the receiving radio interface is active but nobody in the network is transmitting, idle listening occurs. If the traffic pattern is known in advance, as in the relevant case of periodic sensing, proactive reduction of idle listening (PRIL) noticeably lowers energy waste by disabling receivers when no frames are expected for them. Optimal PRIL operation demands that, at any time, the transmitter and receiver sides of a link have a coherent view of its state (either enabled or disabled). However, this is not ensured in the presence of acknowledgment frame losses. This paper presents and analyzes some strategies to cope with such events. An extensive experimental campaign has been carried out through discrete event simulation to determine what consequences above errors may have from both a functional and performance viewpoint. Results show that, although no strategy is optimal in all circumstances, different solutions can be profitably adopted depending on the specific operating conditions.
翻译:在无线传感器网络中,无线感应器的寿命可以通过减少通信用能耗而扩大。 时间档频道选择的方式,通过按照预先确定的时间安排进行框架交换来追求这一目标,这有助于减少值勤周期。 不幸的是,每当接收的无线电界面活跃,但网络中没有人在传输时,就会出现闲置的监听。如果事先知道交通模式,例如在定期遥感的相关案例中,主动减少闲置监听(PRIL)会明显减少能源浪费,因为没有预设框架的接收器会因此令接收器失能。 最优化的 Prial 操作要求,一个链接的发报机和接收器的侧面随时能够对其状态有一个一致的视角( 要么启用, 要么禁用 要么 禁用 ) 。 但是, 在存在确认框架损失的情况下, 这一点得不到保证。 本文介绍并分析了一些应对此类事件的战略。 通过离散事件模拟进行了广泛的实验活动,以确定从功能和性能角度看上述错误可能带来什么后果。 结果表明,尽管在任何情形下都没有最佳的战略,但根据具体操作条件,不同的解决方案都可以被采用。