一、课程简介与课程目标

数字建造是现代信息技术与现代建造技术深度融合的产物。数字建造不仅仅是新的建造方式，更是新的建造体系。结合当前我国工业建造背景，《数字建造》课程将系统论述数字建造的产生背景、发展过程、概念内涵、支撑技术和产业变革趋势，让学生对数字建造有一个全面而深入的了解。课程内容涵盖建筑数字化设计、工程结构参数化设计、工程数字化施工、建筑机器人、建筑结构安全监测与智能评估、建筑工程数字化运维服务等多个方面，对数字建造在工程设计、施工、运维全过程中的相关技术与管理问题进行全面地讲授，帮助学生了解学习数字技术在工程建造实践中的广泛应用。通过学习数字建造的理论方法和技术框架，学生可以培养辩证思维能力，提升解决复杂工程问题的能力。建设本在线课程，有助于学生自主地、有针对性地学习，通过网络平台，教学资源可以得到更广泛的共享与传播，教学内容可以得到及时补充更新，最新的数字建造技术发展和行业趋势得以为学生所了解掌握，保证时效性和前瞻性的同时，还能提升学生对数字建造行业的发展信心。这样一套在线课程的建设，对于培养具有创新精神和实践能力的高素质人才，推动我国建筑行业的数字化、智能化、绿色化发展，具有重要的意义。同时，课程内容也紧密结合了国家需求战略和建筑业的升级转型，让学生了解到信息技术、人工智能技术、物联网、大数据等在数字建造中的应用，提升学生对我国数字建造技术及应用发展的认同感和自豪感。

本课程将深入探讨数字建造的内涵与框架体系，全方位覆盖人工智能及其在土木工程中的应用，包括建筑工业化、大数据驱动的工程决策、工程软件与数字化设计、智慧交通与道路优化、建筑产业互联网等多个关键领域，课程还将融合现代项目管理最新理论，以及结合我国工程项目管理制度的改革与实践，通过高校科学研究与企业创新实践多重视角，紧跟研究前沿和行业最佳实践脚步，全方位帮助学生理解并掌握数字建造在工程设计、施工、运维即整个生命周期中的关键技术与管理策略，帮助学生熟练运用所学知识，在工程实践中解决实际问题，成为具有创新能力和国际视野的数字建造领域专业人才。

二、课程信息

授课教师：马灵教授

日程：第2～9周，每周二、四7～8节，C12-N302

成绩分配：平时成绩40%（课程考勤20%+小组汇报20%）+结课报告60%

推荐教材

《数字建造导论》，丁烈云，北京，中国建筑工业出版社，2019.12

《工程项目管理信息分析》，骆汉宾，中国建筑工业出版社，2021.12

《数字建造项目管理概论》，骆汉宾，机械工业出版社，2021.01

小组项目

（1）学生需要根据课程研讨主题成立学习小组（每5人一组，其中包括一个小组负责人），共同完成课程项目。每个小组负责人需在指定日期前向助教提交小组成员名单。

（2）每组同学自主查找国内外相关案例或前沿研究，解析对应技术应用过程和效果，制作PPT并在课堂分享，汇报内容包括但不限于项目背景、关键技术及原理、实施效果分析、创新点及对自己的研究启示等。

（3）课程结束后，每个小组需要提交一份课程结课报告，报告内容包括但不仅限于引言、研究背景、研究现状、关键技术及原理、技术实施效果分析、领域趋势分析、研究创新点、个人启示总结、参考文献、附录、小组分工等。结课报告任务应公平分配，强调独立性和协作性，小组分工部分务必撰写明确。

三、课程时间安排

考核方式

（1）平时成绩（40%）

①课程考勤（20%）

要求各位同学不得无故缺课，如需请假须在课前持经批准的请假条向助教请假，无故旷课将扣除该次课程的考勤分数；

②小组汇报（20%）

要求每组同学根据课程研讨主题，自主查找国内外相关案例或前沿研究，解析对应技术应用过程和效果，制作PPT并分享，汇报内容包括但不限于项目背景、关键技术及原理、实施效果分析、创新点及对自己的研究启示等；

2024年4月25日课堂上进行小组汇报，汇报时间每组5分钟；请各组以组为单位在汇报前一天将PPT提交至助教邮箱qiufengchn@hust.edu.cn。

（2）结课报告（60%）

提交材料：每组学生共同完成并提交 5000 字左右课程报告，报告内容包括但不仅限于引言、研究现状、趋势分析、总结、参考文献、附录等；

提交方式：提交电子版文档至助教邮箱qiufengchn@hust.edu.cn。

提交时间：2024年5月25日截止，若无特殊原因，延迟一周以内提交扣除20%的分数，超过一周则按未提交处理。

四、文献查询网站

1、中文

知网：https://www.cnki.net/

万方：https://g.wanfangdata.com.cn/index.html

维普：http://lib.cqvip.com/

CSSCI：http://cssci.nju.edu.cn/

华中科技大学BIM工程中心：http://bim.hust.edu.cn/index.htm

2、英文

ScienceDirect:https://www.sciencedirect.com/

EI:https://www.engineeringvillage.com/search/quick.url

Wiley:https://onlinelibrary.wiley.com/

Springer:https://link.springer.com/

Google scholar:https://ac.scmor.com/

五、附件

PPT

01.数字建造导论

02.基于模型定义的工程产品

03.工程物联网

04.制造-建造生产模式

05.建造服务化

06.建造平台化

报告模板word

六、推荐阅读

1、数字建造框架体系

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[9] 毛超, 彭窑胭. 智能建造的理论框架与核心逻辑构建 [J]. 工程管理学报, 2020, 34(5):1–6.

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2、工程信息化模型

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3、土木工程人工智能

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[8] Chen C., Huang J., Wu D., & Tu, X. Interval type-2 fuzzy disturbance observer-based T–S fuzzy control for a pneumatic flexible joint. IEEE Transactions on Industrial Electronics, 69(6), 5962-5972, 2022.

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[10] Fang W., Ding L., Love P. E., Luo H., Li, H., Pena-Mora, F., ... & Zhou, C. Computer vision applications in construction safety assurance. Automation in Construction, 110, 103013, 2020.

4、大数据驱动的工程决策

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5、工程物联网

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