%0 Conference Paper %1 Zinn:works:2010 %A Zinn, Daniel %A Hart, Quinn %A Ludascher, Bertram %A Simmhan, Yogesh %B Workshop on Workflows in Support of Large-Scale Science (WORKS) %D 2010 %I IEEE %K cloud, escience, peer reviewed streaming, usc, workflow, %P 1--8 %R 10.1109/WORKS.2010.5671841 %T Streaming satellite data to cloud workflows for on-demand computing of environmental data products %U http://ceng.usc.edu/~simmhan/pubs/zinn-works-2010.pdf %X Environmental data arriving constantly from satellites and weather stations are used to compute weather coefficients that are essential for agriculture and viticulture. For example, the reference evapotranspiration (ET0) coefficient, overlaid on regional maps, is provided each day by the California Department of Water Resources to local farmers and turf managers to plan daily water use. Scaling out single-processor compute/data intensive applications operating on realtime data to support more users and higher-resolution data poses data engineering challenges. Cloud computing helps data providers expand resource capacity to meet growing needs besides supporting scientific needs like reprocessing historic data using new models. In this article, we examine migration of a legacy script used for daily ET<inf>0</inf> computation by CIMIS to a workflow model that eases deployment to and scaling on the Windows Azure Cloud. Our architecture incorporates a direct streaming model into Cloud virtual machines (VMs) that improves the performance by 130% to 160% for our workflow over using Cloud storage for data staging, used commonly. The streaming workflows achieve runtimes comparable to desktop execution for single VMs and a linear speed-up when using multiple VMs, thus allowing computation of environmental coefficients at a much larger resolution than done presently.

@inproceedings{Zinn:works:2010, abstract = {Environmental data arriving constantly from satellites and weather stations are used to compute weather coefficients that are essential for agriculture and viticulture. For example, the reference evapotranspiration (ET0) coefficient, overlaid on regional maps, is provided each day by the California Department of Water Resources to local farmers and turf managers to plan daily water use. Scaling out single-processor compute/data intensive applications operating on realtime data to support more users and higher-resolution data poses data engineering challenges. Cloud computing helps data providers expand resource capacity to meet growing needs besides supporting scientific needs like reprocessing historic data using new models. In this article, we examine migration of a legacy script used for daily ET<inf>0</inf> computation by CIMIS to a workflow model that eases deployment to and scaling on the Windows Azure Cloud. Our architecture incorporates a direct streaming model into Cloud virtual machines (VMs) that improves the performance by 130% to 160% for our workflow over using Cloud storage for data staging, used commonly. The streaming workflows achieve runtimes comparable to desktop execution for single VMs and a linear speed-up when using multiple VMs, thus allowing computation of environmental coefficients at a much larger resolution than done presently.}, added-at = {2023-04-07T07:37:58.000+0200}, author = {Zinn, Daniel and Hart, Quinn and Ludascher, Bertram and Simmhan, Yogesh}, biburl = {https://www.bibsonomy.org/bibtex/292accf1d9497df3b4f5780dbb018eb0c/vinayaka2000}, booktitle = {Workshop on Workflows in Support of Large-Scale Science (WORKS)}, doi = {10.1109/WORKS.2010.5671841}, interhash = {0fee12da111927c918cf0ea452fbfea3}, intrahash = {92accf1d9497df3b4f5780dbb018eb0c}, keywords = {cloud, escience, peer reviewed streaming, usc, workflow,}, month = {November}, owner = {Simmhan}, pages = {1--8}, publisher = {IEEE}, timestamp = {2023-04-07T07:37:58.000+0200}, title = {Streaming satellite data to cloud workflows for on-demand computing of environmental data products}, url = {http://ceng.usc.edu/~simmhan/pubs/zinn-works-2010.pdf}, year = 2010 }