Geoinstance is defined in several ISO standards, most notably ISO 19107—Geographic Information – Conceptual Schema, and ISO 19112—Geographic Information – Spatial Reference System – Organization and Definitions. These standards prescribe that a geoinstance be uniquely identifiable and capable of linking to its associated feature type, spatial and temporal coverage, and any hierarchical or relational information. For example, a particular stretch of the Seine River from Paris to the English Channel is a distinct geoinstance of the generic “river” feature type, possessing its own coordinates, length, and flow metrics.
Applications of the geoinstance concept are widespread. Urban planners use geoinstances to track individual streets or zoning parcels for redevelopment projects. Environmental scientists model the spread of pollutants by treating each affected area as a separate geoinstance, facilitating targeted mitigation. In asset management, utilities identify each power line segment as a geoinstance to monitor maintenance schedules and fault history. The approach also improves interoperability across systems, allowing datasets from different organizations—such as national mapping agencies and private surveyors—to be merged consistently.
Future developments point to greater integration of geoinstances with linked data architectures and sensor‑driven IoT streams, enabling real‑time updates of geographic features. The precise formalization of geoinstance semantics continues to evolve, but its core role as a bridge between theoretical geographic concepts and operational spatial data remains fundamental to modern geographic information practices.