生物多样性

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国家植物园体系AI能力建设:参考模型、评价指标与应用架构

陈建平, 钟鑫, 陈彬, 葛斌杰, 杜诚, 高燕萍, 郭莉, 金冬梅, 马其侠, 胡永红*   

  1. 上海辰山植物园,华东植物迁地保护与利用国家林业和草原局重点实验室,上海 201602
  • 收稿日期:2026-04-09 修回日期:2026-05-14 接受日期:2026-05-31
  • 通讯作者: 胡永红

AI capability development for China’s National Botanical Garden System: A reference model, maturity assessment framework, and application architecture

Jianping Chen, Xin Zhong, Bin Chen, Binjie Ge, Cheng Du, Yanping Gao, Li Guo, Dongmei Jin, Qixia Ma, Yonghong Hu*   

  1. Key Laboratory of East China Plant Conservation and Utilization, National Forestry and Grassland Administration, Shanghai Chenshan Botanical Garden , Shanghai, 201602, China
  • Received:2026-04-09 Revised:2026-05-14 Accepted:2026-05-31
  • Contact: Yonghong Hu

摘要: 随着国家植物园体系建设的推进,数字化与智能化已成为提升植物多样性迁地保护效能的关键。针对当前植物园AI应用缺乏顶层设计与量化评估工具的现状,本文结合上海辰山植物园实践,提出了面向国家植物园体系的AI能力建设参考模型(national botanical gardens - AI capability reference model, NBG-AICRM)。该模型按照“基础支撑–数据获取–数据治理–智能分析–场景应用”的逻辑,构建了基础设施层、数据感知层、数据管理层、智能分析层和应用场景层5个逻辑层级,涵盖25个关键能力项与若干扩展能力项,并制定了Level 0–5级的成熟度评价量表。在此基础上,提出了应用场景驱动的逆向架构设计方法与“智能保育九宫格”体系。为验证模型的架构设计指导作用,开发了基于大语言模型(LLM)的“智能保育管家(smart plant attendant, SPA)”系统,通过Text-to-SQL技术实现了自然语言驱动的业务分析。初步应用表明,NBG-AICRM能有效弥补植物园智慧化规划缺口,为国家植物园“数据–智能–业务”的深度融合提供理论范式与实践路径。

关键词: 国家植物园, 人工智能, 参考模型, 能力成熟度, 智能保育, 大语言模型

Abstract

Aims: The development of China’s National Botanical Garden System has made digitalization and artificial intelligence (AI) increasingly important for enhancing the effectiveness of ex situ plant conservation. However, AI applications in many botanical gardens remain fragmented, with limited system-level design and few quantitative tools for capability assessment. This study aims to address this gap by constructing a comprehensive AI capability reference model, an associated maturity assessment framework, and an application architecture tailored to the National Botanical Garden system. 

Methods: Grounded in practical experience at Shanghai Chenshan Botanical Garden, we developed the National Botanical Gardens–AI Capability Reference Model (NBG-AICRM). The model follows a bottom-up architecture that links infrastructure support, data acquisition, data governance, intelligent analytics, and scenario-based applications. It consists of five logical layers—infrastructure, data sensing, data management, intelligent analytics, and application scenario—which together cover 25 key capability items and several extended items. Each capability item is assessed using a six-level maturity scale from Level 0 to Level 5. Based on this framework, we formulated an application-scenario-driven reverse architecture design method and a "Smart Conservation Matrix", a nine-grid strategic framework that maps conservation priorities to AI solutions. To validate the architectural guidance of the model, we built the Smart Plant Attendant (SPA), a large language model-based system that uses Text-to-SQL technology to support natural-language-driven, management-oriented analysis of conservation data. The system was trialed at Shanghai Chenshan Botanical Garden. 

Results: The NBG-AICRM provided a structured diagnosis of AI maturity levels, identified specific capability gaps in infrastructure and algorithm application, and outlined a phased upgrade path. The SPA system converted natural language queries into executable SQL statements, enabling conservation staff to retrieve and analyze conservation-relevant information—such as living-collection status trends and the representation of endangered species—without writing code. The initial deployment demonstrated that the model can help address the planning gap in the AI-enabled transformation of botanical gardens and strengthen the linkage among heterogeneous data resources, AI technologies, and day-to-day conservation operations. 

Conclusion: The NBG-AICRM and its companion design methods offer a unified and replicable reference framework for building AI capabilities across China’s national botanical garden system. By formalizing maturity assessment and application architecture, this approach provides both a theoretical paradigm and a practical pathway for integrating data, intelligence, and conservation operations, thereby supporting the digital transformation of plant ex situ conservation. It may also provide a basis for coordinating future AI investment, capability planning, and policy support within the national botanical garden system.

Key words: national botanical garden, artificial intelligence, reference model, capability maturity, intelligent conservation, large language model (LLM)