Abstract
Over the past few decades, the global population and the built environment’s vulnerability to natural hazards have risen dramatically. As a result, decisive actions, such as the SENDAI framework, have emerged to foster a global culture of successful disaster risk reduction policies, including actions to mitigate the social and economic impact of geohazards. The effective study of natural disasters requires meticulous and precise monitoring of their triggering factors, with ground- and space-based techniques. The integration of GNSS and SAR observations through the establishment of permanent infrastructures, i.e., Continuously Operating Reference Stations (CORS) networks and arrays of Corner Reflectors (CRs), may form a seamless ground displacement monitoring system. The current research literature provides fragmented guidelines, regarding the co-location of SAR and GNSS permanent infrastructures. Furthermore, there exist no guidelines for the determination of the most suitable locations using a holistic approach, in terms of criteria and required data. The purpose of this paper is to present a semi-automatic multicriteria site suitability analysis and evaluation of candidate sites for the installation of a permanent CORS and two CRs; one for each pass, taking into account various parameters and criteria. The first results demonstrate that the collocation of SAR and GNSS permanent infrastructures, utilizing a holistic criteria-based approach, is successful and complies with all the literature’s requirements.
Highlights
The collocation of permanent infrastructures, such as GNSS continuously operating reference station (CORS) networks and Interferometric Synthetic Aperture Radar (InSAR)Corner Reflectors (CRs) arrays, represents the state of the art, in terms of dedicated sensors for seamless space-based monitoring of geohazards, towards the fulfilment of important incentives on disaster risk reduction, such as the SENDAI framework [1]
This research revolved around the presentation of a new, semi-automatic process, to determine the most locations for the colocation of GNSS Continuously Operating Reference Stations (CORS), with InSAR CRs in the framework of the establishment of strategic permanent infrastructures
The proposed methodology involves three major steps; the criteria were derived from the guidelines set by international authorities on GNSS and the current scientific literature on CR installation
Summary
The collocation of permanent infrastructures, such as GNSS continuously operating reference station (CORS) networks and Interferometric Synthetic Aperture Radar (InSAR)Corner Reflectors (CRs) arrays, represents the state of the art, in terms of dedicated sensors for seamless space-based monitoring of geohazards, towards the fulfilment of important incentives on disaster risk reduction, such as the SENDAI framework [1]. The collocation of permanent infrastructures, such as GNSS continuously operating reference station (CORS) networks and Interferometric Synthetic Aperture Radar (InSAR). The two space-based techniques can be combined by determining a known displacement rate, generated from GNSS, to an InSAR 4.0/). A new co-located GNSS/SAR infrastructure has been established in Cyprus, in the framework of the CyCLOPS project Monitoring and Prevention System) [8] This project revolves around the formation of a strategic research infrastructure unit for geohazard monitoring, in Cyprus and the Southeastern Mediterranean Region. CyCLOPS is comprised of permanent collocated multisensor configurations, spread throughout the country for monitoring geohazards and solid earth processes. CyCLOPS is formed of the following two major parts: a novel multiparametric network (MPN) of sensors and an operation center (OC).
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