生成树协议 meaning in Chinese
spanning-tree protocol
stp:spanning tree protocol
stspanning tree protocol
Examples
- These lemmas together with spanning tree protocol and local address forwarding information for transparent bridges are taken to fulfil physical topology discovery in subnet finely
以引理为基础,利用生成树协议和地址转发表,解决了对于网内物理拓扑的正确发现,更细致地显示整个网络拓扑。 - Redundant power supplies , hot - swappable modules and spanning tree protocol ( stp ) support are all mandatory elements of a backbone switch , as is support for emerging switch technologies , including virtual lans
具有冗余能力的电源、可热插拔的模块和对生成树协议( stp )的支持都是基干交换机必备的成分,实际上它支持新出现的交换技术,如虚拟局域网。 - The creativity of the work in the paper can be shown as the following four aspects : ( 1 ) for single subnet , the condition of simple link judgement is added into the ptda , so the algorithm is improved well ; ( 2 ) for multiple subnets , the ptda becomes more effective , benefited from use of breadth - first - search algorithm of graph , port - deletion method etc ; ( 3 ) due to suitable adoption of the three protocols stp , snmp and arp , the ptda based on spanning tree protocol can get very effective and correct ; ( 4 ) owing to the employment of ieee802 . 1 q , the ptda of vlan is all - purpose to some extent
本文的创新之处主要体现在以下四个方面:在单子网物理拓扑发现算法中,增加了判断简单连接的条件,使算法更加完善;在多子网物理拓扑发现算法中采用图的广度优先遍历方法、端口删除方法等,该算法更加有效;在生成树协议物理拓扑发现算法中,正确使用stp 、 snmp和arp三种协议,物理拓扑发现非常准确;在vlan物理拓扑发现算法中,正确运用了ieee802 . 1q协议,该算法具有通用性。 - In recent years , it has been attracted considerable attention for a mass of researchers on networks in world , and become the hot research area of computer networks , in particular , has been widely used in network fault - location , performance measurement and count expense etc . based on careful analysis on related theory , technique and application of the topology discovery in world , the author first proposes a new physical topology discovery algorithm ( ptda ) for single subnet , next introduces the new algorithm into multi - subnet case , as a result , puts forward a new ptda for multiple subnets
拓扑发现广泛应用于网络故障定位、性能测试和计费管理等方面。本文在深入分析国内外拓扑发现相关理论、技术和应用的基础上,提出了单子网物理拓扑发现算法,将单子网物理拓扑发现算法扩展到多子网中,并提出多子网物理拓扑发现算法。在研究单子网和多子网物理拓扑发现算法的基础上,提出了基于生成树协议的物理拓扑发现算法。