Ocean acidification is one of the parameters that affect underwater wireless sensor network routing protocols. The underlying network-level metrics of sensor nodes correspond to depth-dependent interactions. The spatial relevancy of sensor nodes varies drastically due to the mobility of the ocean column. In this work, complexity of the underwater environment and its characteristics are fed along with the sensor node capabilities of internetworking and its communication void. The wireless sensor node embeds medium access control layer timing of sensor packet transmission associated with its communication range and underwater characteristics of transmission and absorption losses. Underwater routing protocol for void avoidance transmission probability (UWRPVA-TP) is proposed, and sensors are deployed across diverse depths. Multi-hop communications as a function of depth-dependent attenuation across the ocean columns and their transmission probabilities have been calculated under mobility scenarios. The simulation result of UWRPVA-TP has been validated for the protocol using different attenuation models for energy consumption and number of alive nodes. Finally, the packet reliability ratio and deadline miss ratio has been calculated to understand the application of the time complexity associated with packet transfer.

海洋酸化是影响水下无线传感器网络路由协议的参数之一。传感器节点的底层网络级度量对应于深度相关的交互。由于海柱的移动性，传感器节点的空间相关性变化很大。在这项工作中，水下环境的复杂性及其特征与互联网络的传感器节点能力及其通信空白一起被提供。无线传感器节点嵌入介质访问控制层，传感器数据包传输的时序与其通信范围以及水下传输和吸收损耗特性相关。提出了用于避让传输概率的水下路由协议（UWRPVA-TP），并将传感器部署在不同的深度。多跳通信作为跨海柱的深度相关衰减的函数及其传输概率已在移动场景下进行了计算。UWRPVA-TP 的仿真结果已经验证了该协议使用不同的能量消耗和活动节点数衰减模型。最后，计算了数据包可靠性比和截止期限未命中率，以了解与数据包传输相关的时间复杂度的应用。