Classification and Evaluation of Extended PICS (EPICS) on a Global Scale for Calibration and Stability Monitoring of Optical Satellite Sensors

Juliana Fajardo Rueda,Larry Leigh,Cibele Teixeira Pinto,Morakot Kaewmanee,Dennis Helder

doi:10.3390/rs13173350

Juliana Fajardo Rueda, Larry Leigh + Show 3 more

Open Access

https://doi.org/10.3390/rs13173350

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Journal: Remote Sensing	Publication Date: Aug 24, 2021
Citations: 5	License type: CC BY 4.0

Affiliation: South Dakota State University

Abstract

Historically stable areas across North Africa, known as pseudo invariant calibration sites (PICS), have been used as targets for the calibration and monitoring of optical satellite sensors. However, two major drawbacks exist for these sites: first is the dependency on a single location to be always invariant, and second is the limited amount of observation achieved using these sites. As a result, longer time periods are necessary to construct a dense dataset to assess the radiometric performance of on-orbit optical sensors and confirm that the change detected is sensor-specific rather than site-specific. This work presents a global land cover classification to obtain an extended pseudo invariant calibration site (EPICS) on a global scale using Landsat-8 Operational Land Imager (OLI) data. This technique provides multiple calibration sites across the globe, allowing for the building of richer datasets in a shorter time frame compared to the traditional approach (PICS), with the advantage of assessing the calibration and stability of the sensors faster, detecting possible changes sooner and correcting them accordingly. This work identified 23 World Reference System two (WRS-2) path/row locations around the globe as part of the global EPICS. These EPICS have the advantage of achieving multiple observations per day, with similar spectral characteristics compared to traditional PICS, while still producing a temporal coefficient of variation (ratio of temporal standard deviation and temporal mean) less than 4% for all bands, with some as low as 2.7%.

Highlights

Sites across North Africa for this Global Cluster 13 are named GC13-NA, and the optimal locations selected after processing, those regarded as a global extended pseudo invariant calibration site (EPICS), are called the Optimal Global Cluster 13 (GC13-O)
Considering the results found for C13, and how Hasan et al [10] evaluated and showed North Africa’s potential as an EPICS, 16 optimal WRS-2 path/row(s) in North
Considering the potential of C13 as an EPICS, one of the 160 clusters obtained in this classification that exhibited similar spectral characteristics to C13 was selected as a global

Summary

Introduction

To guarantee comparability between data collected from different satellites, radiometric calibration is essential. This calibration can be conducted using diverse methods, such as pre-launch, on-board, and vicarious calibration. Pre-launch calibration provides a reference to which the post-launch calibration is compared and is achieved through a variety of techniques in the laboratory; for instance, an integrating sphere is widely used for performing this calibration. Since this device is used as a reference, National Institute of Standards and Technology (NIST)

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