The long term record of remote sensing product shows the land surface parameters with spatial and temporal change to support regional and global scientific research widely. Remote sensing product with different sensors and different algorithms is necessary to be validated to ensure the high quality remote sensing product. Investigation about the remote sensing product validation shows that it is a complex processing both the quality of in-situ data requirement and method of precision assessment. A comprehensive validation should be needed with long time series and multiple land surface types. So a system named as land surface remote sensing product is designed in this paper to assess the uncertainty information of the remote sensing products based on a amount of in situ data and the validation techniques. The designed validation system platform consists of three parts: Validation databases Precision analysis subsystem, Inter-external interface of system. These three parts are built by some essential service modules, such as Data-Read service modules, Data-Insert service modules, Data-Associated service modules, Precision-Analysis service modules, Scale-Change service modules and so on. To run the validation system platform, users could order these service modules and choreograph them by the user interactive and then compete the validation tasks of remote sensing products (such as LAI ,ALBEDO ,VI etc.) . Taking SOA-based architecture as the framework of this system. The benefit of this architecture is the good service modules which could be independent of any development environment by standards such as the Web-Service Description Language(WSDL). The standard language: C++ and java will used as the primary programming language to create service modules. One of the key land surface parameter, albedo, is selected as an example of the system application. It is illustrated that the LAPVAS has a good performance to implement the land surface remote sensing product validation.
[1]
Silvio Romero de Lemos Meira,et al.
The Analysis Activity in a Systematic SOA-based Architecture Process
,
2010,
2010 14th IEEE International Enterprise Distributed Object Computing Conference Workshops.
[2]
C. Justice,et al.
A framework for the validation of MODIS Land products
,
2002
.
[3]
Qiang Liu,et al.
The Angular and Spectral Kernel-Driven Model: Assessment and Application
,
2014,
IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.
[4]
Jeffrey L. Privette,et al.
EOS global land validation network
,
1999,
IEEE 1999 International Geoscience and Remote Sensing Symposium. IGARSS'99 (Cat. No.99CH36293).
[5]
Jeffrey L. Privette,et al.
MODIS Land Validation Plan
,
1998
.
[6]
Kees M. van Hee,et al.
An SOA-based architecture framework
,
2006,
Int. J. Bus. Process. Integr. Manag..
[7]
Mladen A. Vouk,et al.
Cloud Computing – Issues, Research and Implementations
,
2008,
CIT 2008.
[8]
J. Privette,et al.
VALERI: a network of sites and a methodology for the validation of medium spatial resolution land satellite products
,
2003
.
[9]
Lei Zhang,et al.
SOA-Based Telecom Product Management System Framework
,
2007,
CONFENIS.
[10]
Frédéric Baret,et al.
Developments in the 'validation' of satellite sensor products for the study of the land surface
,
2000
.
[11]
Z. Niu,et al.
Watershed Allied Telemetry Experimental Research
,
2009
.