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大语言模型文献挖掘驱动的网络指标体系与场景差异化分析

徐祺坤 刘娅汐 韩淑娴 张慧峰 皇甫伟

徐祺坤, 刘娅汐, 韩淑娴, 张慧峰, 皇甫伟. 大语言模型文献挖掘驱动的网络指标体系与场景差异化分析[J]. 电子与信息学报. doi: 10.11999/JEIT251120
引用本文: 徐祺坤, 刘娅汐, 韩淑娴, 张慧峰, 皇甫伟. 大语言模型文献挖掘驱动的网络指标体系与场景差异化分析[J]. 电子与信息学报. doi: 10.11999/JEIT251120
XU Qikun, LIU Yaxi, HAN Shuxian, ZHANG Huifeng, HUANGFU Wei. Network Metric System and Scenario-Differentiated Analysis Driven by LLM Literature Mining[J]. Journal of Electronics & Information Technology. doi: 10.11999/JEIT251120
Citation: XU Qikun, LIU Yaxi, HAN Shuxian, ZHANG Huifeng, HUANGFU Wei. Network Metric System and Scenario-Differentiated Analysis Driven by LLM Literature Mining[J]. Journal of Electronics & Information Technology. doi: 10.11999/JEIT251120

大语言模型文献挖掘驱动的网络指标体系与场景差异化分析

doi: 10.11999/JEIT251120 cstr: 32379.14.JEIT251120
基金项目: 国家重点研发计划“网络模态共生演化模型与体系结构”(2023YFB2903901)
详细信息
    作者简介:

    徐祺坤:男,硕士生,研究方向为无线通信网络、多模态网络等

    刘娅汐:女,副教授,研究方向为无线通信网络、6G通感一体化网络等

    韩淑娴:女,硕士生,研究方向为人工智能、边缘计算等

    张慧峰:女,高级工程师,研究方向为新型网络体系架构、智算中心网络等

    皇甫伟:男,教授,研究方向为网络体系结构与理论模型、边缘计算等

    通讯作者:

    刘娅汐 yaxi.ustb@gmail.com

  • 中图分类号: TN915.0

Network Metric System and Scenario-Differentiated Analysis Driven by LLM Literature Mining

Funds: 2023YFB2903901
  • 摘要: 网络指标是网络设计、运维与优化的基础。本文提出一种基于大语言模型(Large Language Model, LLM)的文献挖掘方案,对《IEEE/ACM Transactions on Networking》2023-2024年刊载的583篇文献进行指标提取、术语规范化、场景标注与指标关联量化,并通过双LLM交叉验证和人工抽样复核检验挖掘结果。结果表明,网络指标呈现“少量共性指标+大量长尾专有指标”的结构,不同应用场景所关注的核心指标集及指标关联均具有场景依赖性。本文提出服务质量(Service, S)、资源复用成本 (Multiplexing, M)以及场景适配重构能力(Versatility, V)三类相互独立且可组合的分析维度,为网络架构的设计、部署、运维和优化提供指导。
  • 图  1  LLM驱动的网络领域文献挖掘数据流图

    图  2  DeepSeek与GLM-4指标关联评分一致性散点图

    图  3  网络指标出现篇次排序及其分布

    图  4  不同网络场景出现的篇次及累计占比

    图  5  热点研究网络场景指标热力图

    图  6  非热点研究网络场景指标热力图

    图  7  网络指标体系的S-M-V三维框架示意图

    表  1  出现篇次前15位的核心网络指标

    网络指标出现篇次篇次占比定义
    吞吐量46179.1%单位时间内成功传输的数据总量
    端到端时延43574.6%数据从源端到目的端传输所需的总时间
    误包率34759.5%传输过程中错误数据包占总数据包的比例
    丢包率28448.7%传输过程中丢失数据包占总数据包的比例
    误码率22238.1%传输过程中错误比特数占总比特数的比例
    带宽21536.9%网络信道能够传输数据的最大速率
    资源利用率21436.7%网络资源(如带宽或处理能力)被使用的百分比
    排队时延14424.7%数据包在队列中等待处理的时间
    抖动12120.8%数据包到达时间间隔的变化量
    往返时延11820.2%数据从源端发送到目的端并返回所需的时间
    信噪比11018.9%信号功率与噪声功率的比值,用于衡量信号质量
    传输时延10818.5%数据从发送端到接收端传输所需的时间
    跳数9816.8%数据包从源到目的经过的网络节点数量
    功耗9716.6%网络设备在运行过程中消耗的功率
    流完成时间9115.6%一个数据流从开始传输到完成所需的总时间
    下载: 导出CSV

    表  2  分场景的网络核心指标特征

    网络类型重点关注指标(篇次占比)场景特性描述
    数据中心网络吞吐量(86.9%)大规模流量调度能力基准
    端到端时延(79.8%)任务响应时延的关键约束
    流完成时间(63.6%)拥塞控制的效能表征
    边缘计算网络端到端时延(79.2%)包含传输和计算的总处理时延
    资源利用率(68.8%)跨设备和服务器的负载分配优化
    通信开销(41.7%)参数服务器与客户端之间通信所消耗的资源
    物联网吞吐量(76.7%)单位时间内成功传输的传感器数据量
    端到端时延(66.7%)传感器、执行器与边缘/云端反馈控制的实时性约束
    能耗(56.7%)网络设备在处理和传输数据时的能量消耗
    网络生存周期(31.1%)网络在能量耗尽前的持续运行时间
    采样率(27.8%)传感器支持的每秒采集信号的次数
    IP网络丢包率(67.1%)传输过程中丢失的数据包占总发送数据包的比例
    抖动(47.1%)数据包到达时间间隔的变化量
    移动自组织网络吞吐量(76.2%)动态路径的有效传输速率
    误包率(65.1%)高扰动环境下的传输可靠性衡量
    信干噪比(44.4%)高扰动环境下的无线信道稳定性表征
    软件定义网络吞吐量(90.6%)VNF实例处理网络流量的能力
    实例扩展时延(81.1%)根据负载动态调整规模的时间开销
    区块链网络吞吐量(85.7%)网络单位时间处理的消息数量
    块传播时延(42.9%)分布式共识效率瓶颈
    下载: 导出CSV
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  • 修回日期:  2026-06-29
  • 录用日期:  2026-06-29
  • 网络出版日期:  2026-07-08

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