开源智能体的技术演化与应用场景——以“龙虾”OpenClaw为例

doi:10.13998/j.cnki.issn1002-1248.26-0147

Abstract

Abstract:

[Purpose/Significance] With the rapid advancement of generative artificial intelligence, open-source agents have emerged as a key driving force in reshaping the development paradigm of artificial intelligence. These agents integrate foundation models, tool chains, and collaborative mechanisms to enable autonomous task execution. From the perspective of technological evolution, this paper conducts a systematic analysis of three core issues concerning open-source agents: technological evolution, application scenarios, and security governance, aiming to clarify the evolutionary laws of open-source agents, expand their application boundaries, and provide theoretical and practical references for their standardized development and rational application. [Method/Process] In terms of evolutionary stages, this study proposed that open-source agents have undergone four distinct phases: pre-history of technology (primitive tool integration stage), single-point intelligence (independent task execution stage), systemic intelligence (multi-tool collaborative stage), and ecological intelligence (multi-agent symbiotic stage). This evolution was driven by a shift in focus from relying solely on the capabilities of foundation models to gradually forming a mature agent ecosystem featuring autonomous operation, multi-agent collaboration mechanisms, and cross-platform interoperability. As a prime example of a practice in the ecological intelligence stage, OpenClaw, with its open-source architecture, modular design, and multi-agent collaborative capabilities, marked a paradigm shift in artificial intelligence, moving from "Model as a Service" (MaaS) to "Agent as a Service" (AaaS) and enabling end-to-end task closed-loop management. Regarding application dimensions, a three-tier progressive scenario framework was constructed, encompassing knowledge-intensive assistance (such as academic research and intelligent consulting), tool-intensive execution (such as automated office and industrial control), and collaboration-intensive processes (such as public governance and team collaboration), emphasizing that its core value lies in accomplishing complex end-to-end tasks in a verifiable, auditable, and sustainable manner. In the governance dimension, a four-layer embedded governance framework was proposed to address the security risks and regulatory challenges posed by open-source agents. This framework covers the protocol layer (standard formulation), the platform layer (technical supervision), the execution layer (behavioral constraints), and the ecological layer (industry self-discipline). [Results/Conclusions] This study found that the competitive focus of open-source agents has gradually shifted from the performance of individual models to ecological controllability and governance credibility. As a new type of intelligent entity, whether open-source agents can effectively support diverse application scenarios, such as scientific research, public governance, and industrial production, fundamentally depends on their ability to realize the deep integration of advanced technological capabilities and sound institutional trust. This also provides a core direction for the future development and governance of open-source agents.

Key words: open-source agents, OpenClaw, evolutionary development, application scenarios, security governance, generative artificial intelligence, skill

CLC Number:

TP18

LI Baiyang, REN Shangsheng. Technical Evolution and Application Scenarios of Open-Source Agents:A Case Study of "OpenClaw"[J].Journal of library and information science in agriculture, 2026, 38(4): 23-35.

Figures/Tables 2

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References 58

[1]	龚芙蓉, 陈宇人. 基于大语言模型链式思维提示的学术信息检索教学智能体构建与分析——以武汉大学图书馆《信息素养与实践》课程为例[J/OL]. 图书馆杂志, 1-14[2026-03-16]. .
	Gong Furong, Chen Yuren. Building and analyzing an academic information retrieval teaching agent based on LLM chain-of-thought prompting: A case study of the "Information Literacy and Practice" course at Wuhan university library[J/OL]. Library Journal, 1-14[2026-03-16]. .
[2]	刘细文, 付芸, 孙蒙鸽. 驱动情报工作范式变革的情报智能体技术解构[J]. 图书情报工作, 2025, 69(1): 4-15.
	Liu Xiwen, Fu Yun, Sun Mengge. Technological deconstruction of DIS agent driving the paradigm shift in documentation and information service work[J]. Library and Information Service, 2025, 69(1): 4-15.
[3]	张益东. 多智能体协同的生态化情报分析范式研究[J]. 情报理论与实践, 2025, 48(S1): 38-43.
	Zhang Yidong. Research on ecological intelligence analysis paradigm of multi-agent collaboration[J]. Information Studies: Theory & Application, 2025, 48(S1): 38-43.
[4]	刘细文, 付芸, 韦华楠. 情报智能体——面向“十五五”的科技情报工作新范式[J]. 农业图书情报学报, 2024, 36(12): 20-34.
	Liu Xiwen, Fu Yun, Wei Huanan. DIS agent: New paradigm of S & T documentation and information service for the fifteenth Five-Year Plan[J]. Journal of Library and Information Science in Agriculture, 2024, 36(12): 20-34
[5]	刘炜, 张磊, 嵇婷, 等. 以AI塑形智慧图书馆: 基于智能体的下一代图书馆服务平台[J]. 农业图书情报学报, 2025, 37(5): 15-26.
	Liu Wei, Zhang Lei, Ji Ting, et al. Shaping the smart libraries with AI: An agent-based, next-generation library service platform[J]. Journal of Library and Information Science in Agriculture, 2025, 37(5): 15-26.
[6]	蒲云强, 唐川, 徐婧, 等. 面向科技战略情报分析的多智能体协同系统研究[J]. 情报理论与实践, 2026, 49(3): 170-178.
	Pu Yunqiang, Tang Chuan, Xu Jing, et al. Research on multi-agent collaboration system for strategic intelligence analysis in science and technology[J]. Information Studies (Theory & Application), 2026, 49(3): 170-178.
[7]	殷跃, 张海涛, 刘彦辉, 等. 基于大模型智能体的粮食安全应急情报体系构建研究[J]. 情报理论与实践, 2025, 48(1): 20-30.
	Yin Yue, Zhang Haitao, Liu Yanhui, et al. Research on the construction of food security emergency intelligence system built on large language model based agents[J]. Information Studies (Theory & Application), 2025, 48(1): 20-30.
[8]	吴畑, 胡宜君, 郑冰. 基于大语言模型的图书馆知识服务多智能体协作模型研究[J/OL]. 图书情报工作, 1-14[2026-03-16]. .
	Wu Tian, Hu Yijun, Zheng Bing. Research on the multi-agent collaboration model of library knowledge service based on large language models[J/OL]. Library and Information Service, 1-14[2026-03-16]. .
[9]	郭一若, 袁一鸣. 多智能体驱动的高校图书馆学科服务范式研究[J/OL]. 情报理论与实践, 1-10[2026-03-16]. .
	Guo Yiruo, Yuan Yiming. Research on the subject service paradigm of academic libraries driven by multi-agents[J/OL]. Information Studies: Theory & Application, 1-10[2026-03-16]. .
[10]	郭利敏, 刘悦如, 付雅明. 面向生成式智能体的图书馆系统架构与转型研究[J]. 农业图书情报学报, 2025, 37(12): 36-47.
	Guo Limin, Liu Yueru, Fu Yaming. Design and transformation pathways of library systems driven by generative agents[J]. Journal of Library and Information Science in Agriculture, 2025, 37(12): 36-47.
[11]	储节旺, 樊鑫鑫. 智能体在智慧图书馆中的应用: 特征能力、体系框架与构建路径[J]. 图书情报工作, 2025, 69(14): 52-60.
	Chu Jiewang, Fan Xinxin. Application of agents in smart libraries: Feature capabilities, system framework, and development path[J]. Library and Information Service, 2025, 69(14): 52-60.
[12]	赵宇翔, 付振康, 曾鹏翔, 等. 生成式人工智能驱动下智慧图书馆信息搜索的技术框架及服务模式研究[J]. 中国图书馆学报, 2025, 51(5): 54-66.
	Zhao Yuxiang, Fu Zhenkang, Zeng Pengxiang, et al. Technological framework and service model of information search in smart libraries: A generative artificial intelligence perspective[J]. Journal of Library Science in China, 2025, 51(5): 54-66.
[13]	周其鑫, 汪波. 迈向“智能体城市”: 城市数字治理的进路研判[J]. 学习与实践, 2025(8): 33-44.
	Zhou Qixin, Wang Bo. Towards an "intelligent agent city": Research and prospect of urban digital governance[J]. Study and Practice, 2025(8): 33-44.
[14]	刘逸伦, 黄微, 周思琪. 多智能体协同赋能的突发事件风险情报感知及预警模式研究[J/OL]. 图书情报工作, 1-13[2026-03-16]. .
	Liu Yilun, Huang Wei, Zhou Siqi. Research on the risk intelligence perception and early warning mode of sudden incidents empowered by multi-agent collaboration[J/OL]. Library and Information Service, 1-13[2026-03-16]. .
[15]	周红磊, 张海涛, 刘彦辉, 等. 大模型智能体赋能的重大突发事件情报响应体系研究[J]. 图书与情报, 2025(1): 21-31.
	Zhou Honglei, Zhang Haitao, Liu Yanhui, et al. Research on intelligence response system for major emergencies empowered by LLM-based agents[J]. Library & Information, 2025(1): 21-31.
[16]	任越, 谭科铭, 李泊泳, 等. 人工智能赋能公共数字文化服务效能提升: 垂域AI智能体的构建[J/OL]. 情报资料工作, 1-25[2026-03-16]. .
	Ren Yue, Tan Keming, Li Boyong, et al. Improving the efficiency of public digital cultural services empowered by artificial intelligence: Construction of domain-specific AI agents[J/OL]. Information and Documentation Services, 1-25[2026-03-16]. .
[17]	刘越, 张晶睿. 基于多智能体协作超参数优化的威胁情报实体识别[J/OL]. 情报杂志, 1-11[2026-03-16]. .
	Liu Yue, Zhang Jingrui. Threat intelligence entity recognition based on hyperparameter optimization with multi-agent collaboration[J/OL]. Journal of Intelligence, 1-11[2026-03-16]. .
[18]	王明程, 王高开, 李勇男. 基于大模型智能体的安全风险态势感知框架构建[J]. 情报理论与实践, 2024, 47(7): 190-198.
	Wang Mingcheng, Wang Gaokai, Li Yongnan. Construction of a security risk situational awareness framework based on LLM-based agents[J]. Information Studies (Theory & Application), 2024, 47(7): 190-198.
[19]	陈宇人, 龚芙蓉. 学术检索智能体持续使用意愿形成机制——基于“CNKI检索大师”的模糊集定性比较分析[J]. 图书情报知识, 2026, 43(1): 124-136.
	Chen Yuren, Gong Furong. Formation mechanism of continued usage intention for academic retrieval agents: A fuzzy-set qualitative comparative analysis based on "CNKI retrieval master"[J]. Documentation, Information & Knowledge, 2026, 43(1): 124-136.
[20]	吴江, 贺超城, 朱侯. 集成复杂网络与多智能体仿真的人肉搜索效率研究[J]. 情报学报, 2018, 37(1): 68-75.
	Wu Jiang, He Chaocheng, Zhu Hou. Study of "human flesh search" efficiency combining complex networks with agent-based model[J]. Journal of the China Society for Scientific and Technical Information, 2018, 37(1): 68-75.
[21]	刘耀, 周家辉, 邱武文. 基于大语言模型的人文社科类业务智能体构建平台研究[J]. 情报资料工作, 2024, 45(5): 82-91.
	Liu Yao, Zhou Jiahui, Qiu Wuwen. Research on the platform for business agent construction of humanities and social sciences based on large language model[J]. Information and Documentation Services, 2024, 45(5): 82-91.
[22]	张凯, 郭宇霞, 李亚奇, 等. 面向学术文本知识挖掘任务的大语言模型智能体构建与评测研究[J/OL]. 情报理论与实践, 1-12[2026-03-16]. .
	Zhang Kai, Guo Yuxia, Li Yaqi, et al. Research on the construction and evaluation of large language model agents for academic text knowledge mining tasks[J/OL]. Information Studies: Theory & Application, 1-12[2026-03-16]. .
[23]	韩中亚, 何多魁, 唐中君. 基于多智能体协作推理的用户画像特征提取方法[J/OL]. 情报理论与实践, 1-11[2026-03-16]. .
	Han Zhongya, He Duokui, Tang Zhongjun. A user portrait feature extraction method based on multi-agent collaborative reasoning[J/OL]. Information Studies: Theory & Application, 1-11[2026-03-16]. .
[24]	胡锡晟, 付强, 黄晓林, 等. 基于多模态数据驱动的情报智能体模型构建[J/OL]. 情报杂志, 1-9[2026-03-16]. .
	Hu Xisheng, Fu Qiang, Huang Xiaolin, et al. Construction of an intelligence agent model driven by multi-modal data[J/OL]. Journal of Intelligence, 1-9[2026-03-16]. .
[25]	李明锋, 李欣, 王军杰, 等. 面向情报文本的多智能体无监督事件骨架生成方法[J/OL]. 情报杂志, 1-11[2026-03-16]. .
	Li Mingfeng, Li Xin, Wang Junjie, et al. An unsupervised event skeleton generation method for intelligence texts based on multi-agents[J/OL]. Journal of Intelligence, 1-11[2026-03-16]. .
[26]	齐云飞, 耿秀娟, 宋雪含, 等. 从盲信到反思: 元认知引导智能体对人智交互信任的校准作用[J]. 图书馆论坛, 2026, 46(1): 104-115.
	Qi Yunfei, Geng Xiujuan, Song Xuehan, et al. From blind faith to reflection: The role of metacognition-guided agents in human-AI interaction trust[J]. Library Tribune, 2026, 46(1): 104-115.
[27]	张志豪, 杨子良, 朱作箫, 等. 基于大模型多智能体协作的高价值专利识别方法研究[J/OL]. 现代情报, 1-16[2026-03-16]. .
	Zhang Zhihao, Yang Ziliang, Zhu Zuoxiao, et al. Research on a high-value patent identification method based on large model multi-agent collaboration[J/OL]. Journal of Modern Information, 1-16[2026-03-16]. .
[28]	马潇晗, 欧阳荟, 艾时钟, 等. 基于智能体建模的医疗众筹信息扩散模型与平台策略研究[J]. 信息资源管理学报, 2023, 13(4): 96-110.
	Ma Xiaohan, Ouyang Hui, Ai Shizhong, et al. Diffusion model and platform strategy of medical crowdfunding projects based on agent-based modeling[J]. Journal of Information Resources Management, 2023, 13(4): 96-110.
[29]	Wooldridge M, Jennings N R. Intelligent agents: Theory and practice[J]. The Knowledge Engineering Review, 1995, 10(2): 115-152.
[30]	Franklin S, Graesser A. Is it an agent, or just a program : A taxonomy for autonomous agents[M/OL]//Müller J P, Wooldridge M J, Jennings N R. Intelligent Agents III Agent Theories, Architectures, and Languages. Berlin, Heidelberg: Springer Berlin Heidelberg, 1997: 21-35.
[31]	Krämer W. Kahneman D. Thinking, fast and slow[J]. Statistical Papers, 2014, 55(3): 915.
[32]	Yao Shunyu, Zhao J, Yu Dian, et al. ReAct: Synergizing reasoning and acting in language models[PP/OL]. V3. arXiv (2023-03-10)[2026-03-16]. .
[33]	Schick T, Dwivedi-Yu J, Dessì R, et al. Toolformer: Language models can teach themselves to use tools[PP/OL]. V1. arXiv (2023-02-09)[2026-03-16]. .
[34]	Shinn N, Cassano F, Berman E, et al. Reflexion: Language agents with verbal reinforcement learning[PP/OL]. V4. arXiv (2023-10-10)[2026-03-16]. .
[35]	Masterman T, Besen S, Sawtell M, et al. The landscape of emerging AI agent architectures for reasoning, planning, and tool calling: A survey[PP/OL]. V1. arXiv (2024-04-17)[2026-03-16]. .
[36]	Valmeekam K, Marquez M, Olmo A, et al. PlanBench: An extensible benchmark for evaluating large language models on planning and reasoning about change[PP/OL]. V4. arXiv (2023-11-26)[2026-03-16]. .
[37]	Valmeekam K, Stechly K, Kambhampati S. LLMs still can't plan; can LRMs? A preliminary evaluation of OpenAI's o1 on PlanBench[PP/OL]. V1. arXiv (2024-09-20)[2026-03-16]. .
[38]	Liu Xiao, Yu Hao, Zhang Hanchen, et al. AgentBench: Evaluating LLMs as agents[PP/OL]. V3. arXiv (2025-10-04)[2026-03-16]. .
[39]	BabyAGI[EB/OL]. [2026-03-16]. .
[40]	Yang Hui, Yue Sifu, He Yunzhong. Auto-GPT for online decision making: Benchmarks and additional opinions[PP/OL]. V1. arXiv (2023-06-04)[2026-03-16]. .
[41]	Wu Qingyun, Bansal G, Zhang Jieyu, et al. AutoGen: Enabling next-gen LLM applications via multi-agent conversation[PP/OL]. V2. arXiv (2023-10-03)[2026-03-16]. .
[42]	Hong Sirui, Zhuge Mingchen, Chen Jiaqi, et al. MetaGPT: Meta programming for a multi-agent collaborative framework[PP/OL]. V7. arXiv (2024-11-01)[2026-03-16]. .
[43]	Qian Chen, Liu Wei, Liu Hongzhang, et al. ChatDev: Communicative agents for software development[PP/OL]. V5. arXiv (2024-06-05)[2026-03-16]. .
[44]	Chen Weize, Su Yusheng, Zuo Jingwei, et al. AgentVerse: Facilitating multi-agent collaboration and exploring emergent behaviors[PP/OL]. V3. arXiv (2023-10-23)[2026-03-16]. .
[45]	CrewAI documentation - CrewAI[EB/OL]. [2026-03-16]. .
[46]	LangChain overview[EB/OL]. [2026-03-16]. .
[47]	Wang Jialin, Duan Zhihua. Agent AI with LangGraph: A modular framework for enhancing machine translation using large language models[PP/OL]. V1. arXiv (2024-12-05)[2026-03-16]. .
[48]	Yang J, Jimenez C E, Wettig A, et al. SWE-agent: Agent-computer interfaces enable automated software engineering[PP/OL]. V3. arXiv (2024-11-11)[2026-03-16]. .
[49]	Introducing the model context protocol[EB/OL]. [2026-03-16]. .
[50]	Announcing the Agent2Agent protocol (A 2A)- Google developers blog[EB/OL]. [2026-03-16]. .
[51]	Linux foundation launches the Agent2Agent protocol project to enable secure, intelligent communication between AI agents[EB/OL]. [2026-03-16]. .
[52]	Wang Xingyao, Li Boxuan, Song Yufan, et al. OpenHands: An open platform for AI software developers as generalist agents[PP/OL]. V3. arXiv (2025-04-18)[2026-03-16]. .
[53]	国家信息安全漏洞库通报OpenClaw多个安全漏洞_通信世界网[EB/OL]. [2026-03-16]. .
[54]	钱力, 王茜颖, 刘熠, 等. 科研场景下的智能体技术与应用研究[J]. 农业图书情报学报, 2025, 37(5): 5-14.
	Qian Li, Wang Qianying, Liu Yi, et al. Agent technology and its applications in scientific research[J]. Journal of Library and Information Science in Agriculture, 2025, 37(5): 5-14.
[55]	Gridach M, Nanavati J, El Abidine K Z, et al. Agentic AI for scientific discovery: A survey of progress, challenges, and future directions[PP/OL]. V1. arXiv (2025-03-12)[2026-03-17]. .
[56]	陶庆云, 樊治平. 知识密集型业务流程中知识管理的实施[J]. 东北大学学报(社会科学版), 2006, 8(4): 257-260.
	Tao Qingyun, Fan Zhiping. Implementation of knowledge management in knowledge-intensive business process[J]. Journal of Northeastern University (Social Science), 2006, 8(4): 257-260.
[57]	李兰花, 郭艳婷, 钟宇琢. 基于华为鸿蒙的开源社区多样化协作模式研究[J]. 科学学研究, 2024, 42(7): 1461-1471.
	Li Lanhua, Guo Yanting, Zhong YuZhuo, et al. The diverse coordination patterns in open source community: A study of Huawei OpenHarmony Project[J]. Studies in Science of Science, 2024, 42(7): 1461-1471.
[58]	滕姗姗, 胡奇. 智能体嵌入下体育传媒产业的生态重构、风险谱系、防治路径[J]. 宁夏社会科学, 2025(5): 203-216.
	Teng Shanshan, Hu Qi. Ecological reconstruction, risk pedigree and prevention path of sports media industry with agent embedding[J]. NingXia Social Sciences, 2025(5): 203-216.

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