Abstract
Observation schedules depend upon the accurate understanding of a single sensor’s observation capability and the interrelated observation capability information on multiple sensors. The general ontologies for sensors and observations are abundant. However, few observation capability ontologies for satellite sensors are available, and no study has described the dynamic associations among the observation capabilities of multiple sensors used for integrated observational planning. This limitation results in a failure to realize effective sensor selection. This paper develops a sensor observation capability association (SOCA) ontology model that is resolved around the task-sensor-observation capability (TSOC) ontology pattern. The pattern is developed considering the stimulus-sensor-observation (SSO) ontology design pattern, which focuses on facilitating sensor selection for one observation task. The core aim of the SOCA ontology model is to achieve an observation capability semantic association. A prototype system called SemOCAssociation was developed, and an experiment was conducted for flood observations in the Jinsha River basin in China. The results of this experiment verified that the SOCA ontology based association method can help sensor planners intuitively and accurately make evidence-based sensor selection decisions for a given flood observation task, which facilitates efficient and effective observational planning for flood satellite sensors.
Highlights
More than 1700 operational remote sensing satellites equipped with various sensors deployed on Earth [1] can be used for Earth monitoring, forming a set of integrated and dynamic sensor networks to provide spatial-temporal and thematic observation information
This study introduced a sensor observation capability association (SOCA) ontology model resolved around the task-sensor-observation capability (TSOC) design pattern
The pattern was developed considering the stimulus-sensor-observation (SSO) ontology design pattern, which focuses on facilitating sensor selection in one observation task
Summary
More than 1700 operational remote sensing satellites equipped with various sensors deployed on Earth [1] can be used for Earth monitoring (e.g., floods and landslides), forming a set of integrated and dynamic sensor networks to provide spatial-temporal and thematic observation information. In this context, selecting the right remote sensing satellite sensors to efficiently and effectively accomplish a specific Earth observation task is a key process in remote sensing satellite sensor management [2,3].
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