Research progress on the concept and key technologies of pan-spatial information system

doi:10.13474/j.cnki.11-2246.2026.0511

Abstract

Abstract: [Purposes]In response to the limitations of traditional geographic information systems which primarily focus on Earth's surface and can no longer meet the increasingly complex cross-scale application demands,this study focuses on the pan-spatial information system (PSIS),an important emerging direction in GIS theory.It summarises the background of PSIS development in the context of challenges faced by GIS in the era of big data and analyses its core concepts and modelling theories.[Methods]By systematically reviewing research achievements on PSIS over the past decade,this study identifies and synthesises its main characteristics,key technologies,and typical application cases.[Findings]The findings reveal that PSIS is characterised by diverse spatio-temporal object types,complex and heterogeneous computational environments,highly variable application scenarios,and comprehensive and efficient information processing capabilities.PSIS has already been widely applied in fields such as smart cities and natural resource management.[Conclusions]Future research on PSIS should focus on three main aspects:strengthening theoretical foundations,integrating cutting-edge technologies,and expanding application domains.

Key words: geographic information system, pan-spatial information system, spatio-temporal domain, spatio-temporal object, spatio-temporal objects of multi-granularity

CLC Number:

P208

YIN Xiaoling, BAI Jingwen, YANG Ji, FENG Huihui, LI Yong, DING Xiaohui, HU Hongda, HUANG Wumeng, HOU Zhiwei, WANG Wenpei. Research progress on the concept and key technologies of pan-spatial information system[J]. Bulletin of Surveying and Mapping, 2026, 0(5): 56-63.

References

[1] MCAFEE A,BRYNJOLFSSON E.Big data:the management revolution[J].Harvard Business Review,2012,90(10):60-66.
[2] LI Songnian,DRAGICEVIC S,CASTRO F A,et al.Geospatial big data handling theory and methods:a review and research challenges[J].ISPRS Journal of Photogrammetry and Remote Sensing,2016,115:119-133.
[3] 陆锋,张恒才.大数据与广义GIS[J].武汉大学学报(信息科学版),2014,39(6):645-654.
[4] KIM K J,DOHM J M,WILLIAMS J P,et al.The south Pole-Aitken basin region,moon:GIS-based geologic investigation using Kaguya elemental information[J].Advances in Space Research,2012,50(12):1629-1637.
[5] 周成虎.全空间地理信息系统展望[J].地理科学进展,2015,34(2):129-131.
[6] ZHOU Chenghu.Exploring future GIS visions in the era of the scientific and technological revolution[J].Information Geography,2025,1(1):100007.
[7] 邢丽平,左维,李春来.建立WebGIS的月球三维可视化关键技术[J].天文研究与技术,2014,11(3):299-304.
[8] 华一新.全空间信息系统的核心问题和关键技术[J].测绘科学技术学报,2016,32(4):331-335.
[9] 华一新,周成虎.面向全空间信息系统的多粒度时空对象数据模型描述框架[J].地球信息科学学报,2017,19(9):1142-1149.
[10] 张树清,周成虎,张俊岩,等.泛知识化三维GIS表达模型(UKRM)[J].中国科学(地球科学),2016,46(2):214-228.
[11] 陈祥葱,张树清,丁小辉,等.时空参考框架普适化表达[J].地球信息科学学报,2017,19(9):1201-1207.
[12] YANG Zhenkai,CHEN Minjie,BCHEN D.A study on representation and application of temporal coordinate reference systems in GIS[C]//Proceedings of the 26th International Conference on Geoinformatics.Kunming:IEEE,2018.
[13] 丁小辉,张树清,陈祥葱,等.时空对象行为分类与形式化表达[J].地球信息科学学报,2017,19(9):1195-1200.
[14] 曹一冰,华一新,郭邵萌.多粒度时空对象行为特征的描述方法研究[J].地理信息世界,2018(2):23-29.
[15] 江南,方成,陈敏颉.全空间信息系统认知与表达初探[J].地球信息科学学报,2017,19(9):1150-1157.
[16] 方成,江南.全空间信息系统的空间认知模型研究[J].测绘与空间地理信息,2018,41(12):61-64.
[17] 张政,华一新,张晓楠,等.多粒度时空对象关联关系基本问题初探[J].地球信息科学学报,2017,19(9):1158-1163.
[18] 华一新,赵鑫科,张江水.地理信息系统研究新范式[J].地球信息科学学报,2023,25(1):15-24.
[19] 宋关福,陈勇,罗强,等.GIS基础软件技术体系发展及展望[J].地球信息科学学报,2021,23(1):2-15.
[20] 曾梦熊,张政,张江水,等.时空对象动态行为分布式计算的数据库实现[J].测绘科学技术学报,2024,40(6):638-645.
[21] TEO T A,CHO K H.BIM-oriented indoor network model for indoor and outdoor combined route planning[J].Advanced Engineering Informatics,2016,30(3):268-282.
[22] 余焕鹏.基于三维可视协同工作环境的油气勘探多源数据一体化应用研究[J].河南科技,2020,39(25):130-132.
[23] 程学旗,靳小龙,王元卓,等.大数据系统和分析技术综述[J].软件学报,2014,25(9):1889-1908.
[24] JANOWICZ K,GAO Song,MCKENZIE G,et al.GeoAI:spatially explicit artificial intelligence techniques for geographic knowledge discovery and beyond[J].International Journal of Geographical Information Science,2020,34(4):625-636.
[25] 张永生,张振超,童晓冲,等.地理空间智能研究进展和面临的若干挑战[J].测绘学报,2021,50(9):1137-1146.
[26] GOODCHILD M F.Geographic information system[M]//Encyclopedia of Database Systems.Boston:Springer US,2009:1231-1236.
[27] KOLBE T H,GRÖGER G,PLVMER L.CityGML:interoperable access to 3D city models[M]//Geo-information for Disaster Management.Berlin,Heidelberg:Springer,2005:883-899.
[28] LIU Xin,WANG Xiangyu,WRIGHT G,et al.A state-of-the-art review on the integration of building information modeling (BIM)and geographic information system (GIS)[J].ISPRS International Journal of Geo-Information,2017,6(2):53.
[29] XU X W,DING Lieyun,LUO Hanbin,et al.From building information modeling to city information modeling[J].Journal of Information Technology in Construction,2014,19:292-307.
[30] 安秋生,沈钧毅,王国胤.基于信息粒度与Rough集的聚类方法研究[J].模式识别与人工智能,2003,16(4):412-417.
[31] 苗夺谦,范世栋.知识的粒度计算及其应用[J].系统工程理论与实践,2002,22(1):48-56.
[32] 杜莹,武玉国.全空间信息系统中的时空参考构建与实现[J].测绘工程,2024,33(5):21-28.
[33] 华一新,张江水,曹一冰.基于时空域的全空间数字世界时空对象组织与管理研究[J].地球信息科学学报,2021,23(1):75-83.
[34] 张江水,华一新,曹一冰.基于时空实体的空间信息系统[J].测绘科学,2025,50(2):11-18.
[35] 邱强,秦承志,朱效民,等.全空间下并行矢量空间分析研究综述与展望[J].地球信息科学学报,2017,19(9):1217-1227.
[36] 陈达,崔虎平,苏亚龙.多粒度时空对象可视分析体系初探[J].地理信息世界,2018,25(2):36-39.
[37] 龚健雅,贾文珏,陈玉敏,等.从平台GIS到跨平台互操作GIS的发展[J].武汉大学学报(信息科学版),2004,29(11):985-989.
[38] 陶留锋,徐永洋,吴晔晖,等.全空间地球信息系统软件关键技术与应用[J].软件导刊,2023,22(11):1-8.
[39] 巫细波,杨再高.智慧城市理念与未来城市发展[J].城市发展研究,2010,17(11):56-60.
[40] 杨飞,华一新,李响,等.多粒度时空对象行为驱动的传感设施接入方法[J].测绘科学技术学报,2020,37(5):537-544.
[41] 杨飞,华一新,李响,等.基于多粒度时空对象数据模型的城市基础设施建模与管理[J].地球信息科学学报,2021,23(11):1984-1997.
[42] 张毅,华一新,刘小春,等.面向全空间信息系统的传感设备实时数据管理架构[J].测绘科学技术学报,2021,37(3):301-308.
[43] 刘慧,崔虎平,韦原原,等.基于时空对象的高铁网络建模方法[J].测绘科学技术学报,2021,37(1):104-110.
[44] 钟怡然,胡迪,俞肇元,等.基于多粒度时空对象数据模型的高速公路智能监控系统建模[J].地理与地理信息科学,2022,38(1):110-115.
[45] 马茂鑫,张健钦,崔晓琛,等.一种面向道路养护的多粒度时空对象模型研究[J].测绘科学,2023,48(10):206-215.
[46] 周艳,李妍羲,黄悦莹,等.基于社交媒体数据的城市人群分类与活动特征分析[J].地球信息科学学报,2017,19(9):1238-1244.
[47] 陈文静,李锐,董广胜,等.网络地理信息服务中用户空间访问聚集行为研究[J].地球信息科学学报,2021,23(1):93-103.
[48] 韦原原,江南,陈云海,等.顾及时空对象空间相互作用的疫情风险评估建模与应用[J].地球信息科学学报,2021,23(2):274-283.
[49] CHEN Yunhai,JIANG Nan,CAO Yibing,et al.Visual method of analyzing COVID-19 case information using spatio-temporal objects with multi-granularity[J].Journal of Geographical Sciences,2021,31(7):1059-1081.
[50] 陈敏颉,江南,张政,等.面向网络空间地图的时空实体可视化表达与实现[J].测绘通报,2024(12):48-54.
[51] 陈敏颉,江南,陈达.多粒度时空事件建模与可视化方法初探[J].地理信息世界,2018(2):30-35.
[52] 訾璐,张江水,杨振凯,等.高精地图交通要素对象化建模方法[J].测绘科学技术学报,2020,37(6):636-642.
[53] 郭玥晗,江南,曹一冰,等.多粒度时空对象的校史信息可视化研究[J].测绘科学,2021,46(10):145-150.
[54] 谢雨芮,江南,赵文双,等.基于多粒度时空对象的作战实体对象化建模研究[J].地球信息科学学报,2021,23(1):84-92.
[55] 靖常峰,李佳宁,吴森森,等.基于对象空间的地理场景表达模型与组织管理方法及应用[J].地理学报,2024,79(9):2230-2245.
[56] 王嘉嚇,周睿,袁烨城,等.基于对象模型的污染场地表达方法及案例研究[J].资源科学,2024,46(4):761-774.
[57] 田淙海,于万荣,刘澎,等.气象与环境监测管理可视化设计与实现[J].兵工自动化,2025,44(4):32-36.
[58] 余永鹏,毛兴军,闫建波,等.煤矿地质应急救援信息系统设计与实践[J].煤矿安全,2024,55(1):216-224.
[59] 廖小罕,汤安琪,岳焕印,等.无人机组网遥感:“高频次迅捷”到“全时全域”演进[J].遥感学报,2025,29(6):1515-1528.
[60] 张旭,杨洁,邵智娟,等.中国自然灾害次生突发环境污染事件时空分布及风险特征[J].灾害学,2025,40(4):105-113.