Abstract
Active satellite remote sensors have emerged in the last years in the field of archaeology, providing new tools for monitoring extensive cultural heritage landscapes and areas. These active sensors, namely synthetic aperture radar (SAR) satellites, provide systematic datasets for mapping land movements triggered from earthquakes, landslides, and so on. Copernicus, the European program for monitoring the environment, provides continuous radar datasets through the Sentinel-1 mission with an almost worldwide coverage. This paper aims to demonstrate how the use of open-access and freely distributed datasets such as those under the Copernicus umbrella, along with the exploitation of open-source radar processing software, namely the sentinel applications platform (SNAP) and SNAPHU tools, provided respectively by the European Space Agency (ESA) and the University of Stanford, can be used to extract an SAR interferogram in the wider area of Paphos, located in the western part of Cyprus. The city includes various heritage sites and monuments, some of them already included in the UNESCO World Heritage list. The interferogram was prepared to study the effects of an earthquake to the buildings and sites of the area. The earthquake of a 5.6 magnitude on the Richter scale was triggered on 15 April 2015 and was strongly felt throughout the whole island. The interferogram results were based on Differential Synthetic Aperture Radar Interferometry (D-InSAR) methodology, finding a maximum uplift of 74 mm and a maximum subsidence of 31 mm. The overall process and methodology are presented in this paper.
Highlights
Applications of Earth Observation for cultural heritage have rapidly increased in the last years
After checking that the pair of images were suitable for the task in hand, the two images were coregistered in the sentinel applications platform (SNAP) environment into a stack, selecting the image prior to the earthquake (14f April) as the master and the synthetic aperture radar (SAR) image after the earthquake (26 April) as the slave
Coregistration ensured that each ground target contributed to the same pixel in both the master and the slave images [41]
Summary
Applications of Earth Observation for cultural heritage have rapidly increased in the last years. D-InSAR has been used successfully for monitoring land subsidence [5,6,7,8,9] and uplift, with particular applications such as landslides [10,11,12] and other ground displacements caused by natural occurring phenomena such as earthquakes [13,14,15], volcano eruptions [16,17,18,19], and human activities [20,21]. D-InSAR can be used to detect and monitor, under certain conditions, ground deformations on a centimetric scale, offering an effective method for assessing land movements over large areas [22]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
