MSTP线路路由切换解决方案

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目录1 MSTP故障处理 ·································································································································· 1-11.1 广播风暴故障处理 ····························································································································· 1-11.1.1 故障描述 ································································································································· 1-11.1.2 故障处理流程 ·························································································································· 1-11.1.3 故障处理步骤 ·························································································································· 1-11.2 端口无法快速迁移故障处理··············································································································· 1-21.2.1 故障描述 ································································································································· 1-21.2.2 故障处理流程 ·························································································································· 1-31.2.3 故障处理步骤 ·························································································································· 1-41.3 指定端口长期处于Discarding状态故障处理 ······················································································ 1-51.3.1 故障描述 ································································································································· 1-51.3.2 故障处理流程 ·························································································································· 1-61.3.3 故障处理步骤 ·························································································································· 1-71.4 端口STP DOWN故障处理 ················································································································· 1-81.4.1 故障描述 ································································································································· 1-81.4.2 故障处理流程 ·························································································································· 1-91.4.3 故障处理步骤 ·························································································································· 1-91.5 STP网络流量不稳定故障处理 ········································································································· 1-101.5.1 故障描述 ······························································································································· 1-101.5.2 故障处理流程 ························································································································ 1-111.5.3 故障处理步骤 ························································································································ 1-111.6 设备无法处于同一个MSTP域故障处理···························································································· 1-121.6.1 故障描述 ······························································································································· 1-121.6.2 故障处理流程 ························································································································ 1-121.6.3 故障处理步骤 ························································································································ 1-121.7 故障诊断命令··································································································································· 1-131 MSTP故障处理1.1 广播风暴故障处理1.1.1 故障描述二层网络中存在广播风暴。

MSTP以太电路调试案例分析国际专线电路调试案例分析（重庆分公司）伴随中国经济的蓬勃发展和众多国内企业国际化战略的实施，国际专线电路的需求量越来越大。

另一方面，国际电路的开通也面临涉及段落多、异设备、异厂家、跨国际运营商的复杂环境，开通难度非常大，目前国内运营商和主流厂家可借鉴的经验非常少。

近期，在集团公司的指导下，重庆分公司在国际专线开通中积极探索，积累了初步的经验。

现总结如下，供大家参考。

一、案例背景长安集团是联通公司的重要合作伙伴，也是重庆分公司的重点保障对象。

近期，其连续申请了到日本、英国和意大利的3条国际MSTP 专线电路，我们在电路开通调试初期碰到以下几个问题：日本电路：重庆联通采用华为Metro 1000传输设备EFS单板接入以太网专线业务，对端采用思科15454传输设备，两端业务开通后，测试无法ping通。

英国电路和意大利电路：（长安至英国电路网络图）（长安至英国电路简图）问题一：在9月下旬，由于E段传输路由器还没有调通，协调通过IPSEC隧道临时解决，而调试IPSEC过程中无法调通隧道。

问题二：在12月9日调通E段传输路由后，进行全程联调，ping65500字节的大包有3%丢包；用MSTP仪表打环测试能够达到10M带宽，但两端使用单台电脑下载达不到10M带宽（平均速度不到3M带宽），英国POP点架设FTP服务器端，重庆使用FTP客户端进行下载测试，平均速率是300KB/S，造成用户感知不好。

意大利电路也有同样带宽不能达10M的情况二、案例分析下面对这3条电路的开通、调试过程详细分析如下：日本电路1）、检查网元告警，Metro 1000设备EFS单板有LP_TIM_VC12、LP_SLM_VC12、LP_RDI_VC12告警，说明端设备J2、V5字节设置不一致。

2）、由于对端设备查询这两个字节比较困难，华为默认的J2字节为HuaWei SBS，V5字节为异步，因此对J2、V5字节尝试更改，当J2字节修改为“00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00”（16进制方式16个0）后，LP_TIM-V12告警消失。

一种PMIPv6快速切换路由优化方案的开题报告题目：一种PMIPv6快速切换路由优化方案一、选题背景随着移动互联网的普及，移动节点的数量不断增加，网络的服务质量和用户体验也将面临更大的挑战。

Proxy Mobile IPv6（PMIPv6）是一种无线移动IPv6解决方案，该方案利用网络边缘的移动管理节点(MAG)来管理移动节点的移动过程，从而为移动节点提供无缝的IPv6漫游服务。

在PMIPv6中，移动节点不需要在漫游过程中维护其地址，且无需与向路支持节点进行直接通信，因而可以大大简化移动节点的管理方式和减轻网络边缘的负担。

PMIPv6协议已经被广泛使用，尤其是在大规模的部署中，但在实践中，该协议在处理切换路由时存在潜在的延迟问题。

当一个移动节点从一个MAG切换到另一个MAG时，其原有的流量将受到中断，这将导致网络链接的中断和用户体验的下降。

因此，如何快速切换移动节点的路由成为一个非常重要的问题。

本文旨在探讨一种PMIPv6快速切换路由优化方案，提高移动节点的切换效率和用户体验。

二、研究目标1.探究PMIPv6切换路由的机制和流程2.分析现有的PMIPv6切换路由方案，并分析其优缺点3.提出一种新的PMIPv6快速切换路由优化方案4.基于NS-3模拟平台进行实验，评价新方案在应对不同情况下的表现三、研究内容1.PMIPv6协议及其切换路由机制介绍2.现有的PMIPv6切换路由方案及其分析3.提出一种新的PMIPv6快速切换路由优化方案，并阐述其实现原理4.基于NS-3平台模拟实验，对新方案的性能及可靠性进行评估五、研究意义通过本研究，可以提高PMIPv6处理切换路由的能力和效率，减少切换路由的延迟和导致的服务中断，从而提高用户体验和网络效率。

此外，新模型的提出和实验验证，也为大规模部署PMIPv6在实践中提供了一种有效的方式和方法。

六、研究方法及进度安排第一阶段（2022年3月-2022年6月）：深入探讨PMIPv6协议及其切换路由机制，并对现有的PMIPv6切换路由方案进行分析第二阶段（2022年6月-2022年9月）：基于现有的PMIPv6切换路由方案的分析结果，提出一个新的PMIPv6快速切换路由优化方案，并阐述其实现原理第三阶段（2022年9月-2023年2月）：基于NS-3模拟平台对新方案进行建模和仿真，并对其性能进行评估和分析第四阶段（2023年2月-2023年6月）：根据实验结果和反馈，对新方案进行优化和完善，并撰写相关的论文并提交到相关学术期刊或会议上。

1.1 MSTP 组网处理方案提议1.1.1MSTP技术简朴简介MSTP是Multi-ServiceTransportPlatform旳缩写，它可以将老式旳SDH、以太网、ATM、POS、RPR等多种技术有机融合，通过将多业务汇聚、并高效适配旳方式实现多种业务旳综合传送。

城域网具有覆盖范围广、投资大、业务种类多、竞争剧烈且顾客旳发展难以预测旳特性，基于SDH技术旳MSTP所具有旳多业务综合接入和传送旳特点使其可以在城域网灵活、廉价地提供多种业务。

MSTP技术源于SDH，通过近几年旳不停发展，已经囊括PDH、SDH、POS、以太网、ATM、RPR、SHDSL、DDN等技术于一体，它既可通过多业务汇聚方式实现城域网业务旳综合传送，又可通过自身对多类型业务旳适配性实现业务旳接入和处理，非常适应城域网多种技术相融合旳发展趋势，成为一套相对完善旳城域网技术体系。

从城域数据业务网规定为客户提供全方位SLA服务旳角度来看，MSTP具有受理各类高等级专线业务旳能力，并在实际旳网络应用中发挥作用。

根据租用业务旳SLA服务原则，运行商网络应当可以提供从最高等级到最低等级旳业务，以满足不一样类型客户对专线旳需求。

假如部分最终顾客对运行网络旳理解还不够透彻，以不信任机制来看待租用电路旳话，那么MSTP技术在处理大客户专线需求方面还具有数据网所不具有旳某些特性，如安全性、透明性和可管理性等。

对于真正基于SLA旳银行客户专线服务，MSTP除了提供数据网已经处理旳数据业务之外，还具有信息透明、带宽透明、高安全性和可管理旳高等级业务，更可以恰当地满足客户需求，从而提高网络旳综合竞争力，防止IP网络同质化所导致旳价格战。

因此，从IP数据网旳现实状况和最终顾客对IP数据网旳认知来看，有机地将MSTP技术与IP数据网结合起来，将成为近几年内实现银行客户专线业务旳理想处理方案。

MSTP技术是基于SDH技术发展演变而来旳，因而它天生具有了SDH技术旳众多长处，如组网，业务保护等方面；另首先，MSTP又是对老式SDH技术旳革新，由于大量采用了GFP（通用帧映射规程）、虚级联和LCAS（动态链路调整）等新技术，又容纳了IP/以太网和ATM技术。

MSTP组网类解决方案第一篇：MSTP组网类解决方案中国人民银行西安分行网络升级解决方案中国电信股份有限公司西安分公司2018年5月目录1、中国人民银行西安分行网络现状及需求分析 (3)1.1 中国人民银行西安分行网络现状................................3 1.2中国人民银行西安分行需求分析 (3)2、中国人民银行西安分行解决方案 (4)2.1 方案设计原则................................................4 2.2 中国人民银行西安分行MSTP组网解决方案.. (5)3、MSTP组网方案特点 (5)4、方案优势 (6)1、中国人民银行西安分行网络现状及需求分析1.1 中国人民银行西安分行网络现状中国人民银行西安分行目前的全省广域网线路已运行多年，具体形式为：1.西安分行核心路由器通过CPOS光口与电信方专业传输设备对接，实现9个地市及营业部单位的数据互联；2.目前共开通有11条SDH数字电路，每条电路带宽为10M，每个地市单位同时开通1条SDH数字电路，并通过西安分行路由器和地市及营业部单位路由器进行互联使用；3.每个地市及营业部单位10M带宽承载了公文、视频会议系统等重要业务。

4.经现场与客户网络设备厂家技术人员确认：⎫中心端路由器具备空闲千兆FE电口，并且端口具备划分子接口（VLAN）的功能；⎫地市及营业部单位路由器均空闲有1个以太网端口。

1.2中国人民银行西安分行需求分析中国人民银行西安分行现广域网已经运行多年，随着政务系统信息化建设的推进，现有的网络带宽已经不能满足业务量激增的需要，急需进行升级扩容，具体要求包括：1、将西安分行至9个地市及营业部单位的广域网带宽由10M提升至20M;2、尽可能利旧现有设备实现升速；3、整个网络升级扩容不能影响到正常工作，并且升级后全网的ip 地址不需要变更。

2、中国人民银行西安分行解决方案2.1 方案设计原则针对中国人民银行西安分行广域网升级项目的重要性和特殊性，我们在设计项目解决方案时特别遵循了以下设计原则：λ先进性原则从较高的起点对网络建设进行规划，充分采用先进成熟的网络技术，满足中国人民银行西安分行业务数据传输需要。