multihop transmission
简明释义
多次反射传输
英英释义
例句
1.The efficiency of multihop transmission can significantly reduce energy consumption in mobile ad hoc networks.
多跳传输 的效率可以显著降低移动自组网中的能耗。
2.In wireless sensor networks, multihop transmission is crucial for extending the communication range.
在无线传感器网络中,多跳传输 对于扩展通信范围至关重要。
3.In a mesh network, multihop transmission enables devices to communicate even when they are not in direct range.
在网状网络中,多跳传输 使设备即使不在直接范围内也能进行通信。
4.Implementing multihop transmission allows for better data routing in large-scale IoT systems.
实施多跳传输 可以在大规模物联网系统中实现更好的数据路由。
5.The research focuses on optimizing multihop transmission protocols for improved latency and throughput.
该研究集中于优化多跳传输 协议,以改善延迟和吞吐量。
作文
In the world of wireless communication, the concept of multihop transmission plays a crucial role in enhancing connectivity and efficiency. Essentially, multihop transmission refers to a method where data is transmitted across multiple nodes or hops before reaching its final destination. This technique is particularly useful in scenarios where direct communication between the source and the target is not feasible due to distance or obstacles. By utilizing intermediate nodes, the data can be relayed in smaller segments, thus overcoming limitations imposed by physical barriers and extending the range of communication.One of the primary advantages of multihop transmission is its ability to create a more robust network. In traditional point-to-point communication, if one link fails, the entire transmission can be disrupted. However, in a multihop transmission system, there are multiple paths for the data to take, which increases the likelihood that it will reach its destination even if some links are compromised. This redundancy is particularly important in emergency situations or in remote areas where reliable communication is critical.Moreover, multihop transmission can significantly improve the overall network performance. By allowing data to take advantage of various paths, the system can balance the load among different nodes. This load balancing helps to prevent any single node from becoming overwhelmed, which can lead to delays or packet loss. Additionally, since data can be routed through nodes that are closer to the destination, it can reduce latency and enhance the speed of communication.In the context of mobile ad hoc networks (MANETs), multihop transmission is particularly relevant. These networks are characterized by their dynamic nature, where nodes can join and leave the network at any time. In such environments, establishing a stable communication path can be challenging. However, with multihop transmission, nodes can communicate with each other indirectly through other nodes, facilitating seamless communication despite the constant changes in the network topology.Another important application of multihop transmission is in sensor networks, which are often deployed in areas where traditional infrastructure is lacking. For instance, environmental monitoring systems may consist of numerous sensors distributed over a large area. Instead of requiring each sensor to communicate directly with a central server, they can use multihop transmission to relay their data through nearby sensors. This not only conserves energy but also extends the operational range of the network, as sensors can effectively communicate over longer distances by leveraging the capabilities of their neighbors.Despite the many benefits of multihop transmission, there are also challenges that need to be addressed. One of the main issues is the increased complexity of managing multiple hops. As the number of nodes increases, so does the potential for interference and data collisions, which can degrade the quality of the communication. Therefore, developing efficient routing protocols that can adapt to changing network conditions is essential for optimizing multihop transmission systems.In conclusion, multihop transmission is a vital technique in modern wireless communication that enhances connectivity, improves network robustness, and enables effective data transmission in various applications. By understanding and leveraging this concept, we can create more resilient and efficient communication networks that meet the demands of our increasingly connected world. As technology continues to evolve, the importance of multihop transmission will only grow, paving the way for innovative solutions to complex communication challenges.
在无线通信的世界中,多跳传输的概念在增强连接性和效率方面发挥着至关重要的作用。基本上,多跳传输指的是一种数据通过多个节点或跳跃进行传输的方法,直到达到最终目的地。这种技术在源和目标之间由于距离或障碍而无法直接通信的情况下特别有用。通过利用中间节点,数据可以以较小的片段进行中继,从而克服物理障碍带来的限制,扩展通信范围。多跳传输的主要优点之一是它能够创建一个更强大的网络。在传统的点对点通信中,如果一个链接失败,整个传输可能会中断。然而,在多跳传输系统中,数据有多个路径可供选择,这增加了它到达目的地的可能性,即使某些链接受到损害。这种冗余在紧急情况下或在可靠通信至关重要的偏远地区尤为重要。此外,多跳传输可以显著改善整体网络性能。通过允许数据利用各种路径,系统可以在不同节点之间平衡负载。这种负载平衡有助于防止任何单个节点过载,这可能导致延迟或数据包丢失。此外,由于数据可以通过靠近目的地的节点进行路由,它可以减少延迟并增强通信速度。在移动自组网(MANETs)的背景下,多跳传输尤其相关。这些网络的特点是动态性,节点可以随时加入和离开网络。在这种环境中,建立稳定的通信路径可能具有挑战性。然而,通过多跳传输,节点可以通过其他节点间接通信,尽管网络拓扑不断变化,也能促进无缝通信。多跳传输的另一个重要应用是在传感器网络中,这些网络通常部署在缺乏传统基础设施的地区。例如,环境监测系统可能由分布在大面积上的许多传感器组成。传感器不需要与中央服务器直接通信,而是可以通过附近的传感器使用多跳传输中继它们的数据。这不仅节省了能源,还扩展了网络的操作范围,因为传感器可以通过利用邻居的能力有效地进行长距离通信。尽管多跳传输有许多好处,但也存在需要解决的挑战。主要问题之一是管理多个跳跃的复杂性。随着节点数量的增加,干扰和数据碰撞的潜在风险也随之增加,这可能会降低通信质量。因此,开发能够适应不断变化的网络条件的高效路由协议对于优化多跳传输系统至关重要。总之,多跳传输是现代无线通信中的一种重要技术,它增强了连接性,提高了网络的鲁棒性,并在各种应用中实现了有效的数据传输。通过理解和利用这一概念,我们可以创建更具弹性和高效的通信网络,以满足我们日益互联的世界的需求。随着技术的不断发展,多跳传输的重要性只会增加,为复杂的通信挑战铺平道路。
