IEEE 802.11ax空间复用的动态分布式阈值控制

Sarthak Joshi, Rishabh Roy, R. Bhat, Preyas Hathi, N. Akhtar
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引用次数: 2

摘要

IEEE 802.11ax标准(Wi-Fi 6)在其他特性中采用了一种称为空间重用的特性,在这种特性中,新的传输可以在重叠基本服务集(OBSS)中节点正在进行的干扰传输存在的情况下进行。具体来说,节点可以通过设置一个名为OBSS功率检测电平$(\text{OBSS}_{-}\text{PD}_{\text{level}})$的参数来调整其检测干扰的阈值。当一个节点从OBSS节点听到正在进行的传输时,如果其接收到的信号强度指标(RSSI)低于$\text{OBSS}_{-}\text{PD}_{\text{level}}$,则该节点具有空间重用机会。在空间复用的机会中,节点可以在有限的发射功率(TX_PWR)下进行传输。$\text{OBSS}_{-}\text{PD}_{\text{level}}$和TX_PWR的可行值必须满足IEEE 802.11ax标准规定的一定约束。在这项工作中,我们提出了一种算法,首先获得最大化空间重用机会数量的$\text{OBSS}_{-}\text{PD}_{\text{level}}$阈值,然后在这些$\text{OBSS}_{-}\text{PD}_{\text{level}}$阈值中选择数据包错误率最小的阈值。所涉及的权衡如下:将$\text{OBSS}_{-}\text{PD}_{\text{level}}$设置为高值会增加空间重用机会的数量,但需要传输处于较低的发射功率(由于标准指定的约束),从而导致较高的数据包错误率,反之亦然。该算法根据包错误率动态变化$\text{OBSS}_{-}\text{PD}_{\text{level}}$。仿真结果表明,在不采用空间复用的情况下,采用恒定的$\text{OBSS}_{-}\text{PD}_{\text{level}}$阈值的朴素方法比采用不变的$\text{OBSS}_{-}\text{level}}$阈值的方法具有更高的吞吐量和更低的数据包错误率。当使用该算法实现空间复用时,我们还探讨了使用具有不同优先级和传输参数的QoS队列服务的不同流量模型的性能。
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Dynamic Distributed Threshold Control for Spatial Reuse in IEEE 802.11ax
The IEEE 802.11ax standard (Wi-Fi 6), among other features, adopts a feature called spatial reuse, where new transmissions can be carried out in presence of ongoing, interfering transmissions from nodes in an overlapping basic service set (OBSS). Specifically, a node can adjust its threshold for detecting the interference, by setting a parameter called OBSS Power-Detect level $(\text{OBSS}_{-}\text{PD}_{\text{level}})$. When a node hears an ongoing transmission from an OBSS node, if its received signal strength indicator (RSSI) is below the $\text{OBSS}_{-}\text{PD}_{\text{level}}$, the node is said to have a spatial reuse opportunity. The node can transmit at a limited transmit power (TX_PWR) during the spatial reuse opportunity. The feasible values of $\text{OBSS}_{-}\text{PD}_{\text{level}}$ and TX_PWR must satisfy certain constraints laid out by the IEEE 802.11ax standard. In this work, we propose an algorithm that first obtains $\text{OBSS}_{-}\text{PD}_{\text{level}}$ thresholds for maximizing the number of spatial reuse opportunities, and then selects the one that minimizes the packet error rate among these $\text{OBSS}_{-}\text{PD}_{\text{level}}$ thresholds. The trade-off involved is the following: setting $\text{OBSS}_{-}\text{PD}_{\text{level}}$ to a high value increases the number of spatial reuse opportunities, but necessitates transmissions to be at lower transmit power (due to the constraint specified by the standard) resulting in higher packet error rates, and vice versa. The proposed algorithm dynamically varies $\text{OBSS}_{-}\text{PD}_{\text{level}}$ based on packet error rates. Via simulations, we show that the proposed dynamic algorithm performs better (in terms of achieving a higher throughput and a lower packet error rate) than a naive method which adopts a constant $\text{OBSS}_{-}\text{PD}_{\text{level}}$ threshold and the case when the spatial reuse is not adopted. When the spatial reuse is implemented using the proposed algorithm, we also explore the performance of different traffic models served using QoS queues having different priorities and transmission parameters.
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