Supporting Climate Research using Named Data Networking

Abstract-Climate and other big data applications face substantial problems in terms of data storage, retrieval, sharing and management. While several community repositories and tools are available to help with climate data, these problems still persist and the community is actively looking for better solutions. In this project we apply NDN to support climate modeling applications. The information-centric nature of NDN, where content becomes a first class entity, simplifies many of the problems in this domain. NDN offers lightweight data publication, discovery and retrieval compared to IP-based solutions. However, introducing a new network architecture to a mature domain that routinely produces petabytes of datasets and a plethora of assorted tools to manipulate them, is a risky proposition. The advantages of NDN alone may not be sufficient to overcome the natural inertia. Our approach is to introduce NDN while carefully avoiding undue disruption to existing workflows. To that extent we employ a user interface that employs familiar filesystem operations to publish, discover and retrieve data, integrated with domain-specific translators that automatically convert and publish datasets as NDN objects. We outline the advantages of NDN in this application domain and the challenges we faced during the adaptation. We believe this is the first exercise in applying NDN in an existing, large, mature application domain

Named Data Networking in Climate Research and HEP Applications

The Computing Models of the LHC experiments continue to evolve from the simple hierarchical MONARC[2] model towards more agile models where data is exchanged among many Tier2 and Tier3 sites, relying on both large scale file transfers with strategic data placement, and an increased use of remote access to object collections with caching through CMS's AAA, ATLAS' FAX and ALICE's AliEn projects, for example. The challenges presented by expanding needs for CPU, storage and network capacity as well as rapid handling of large datasets of file and object collections have pointed the way towards future more agile pervasive models that make best use of highly distributed heterogeneous resources. In this paper, we explore the use of Named Data Networking (NDN), a new Internet architecture focusing on content rather than the location of the data collections. As NDN has shown considerable promise in another data intensive field, Climate Science, we discuss the similarities and differences between the Climate and HEP use cases, along with specific issues HEP faces and will face during LHC Run2 and beyond, which NDN could address

Future of networking is the future of Big Data, The

2019 Summer.Includes bibliographical references.Scientific domains such as Climate Science, High Energy Particle Physics (HEP), Genomics, Biology, and many others are increasingly moving towards data-oriented workflows where each of these communities generates, stores and uses massive datasets that reach into terabytes and petabytes, and projected soon to reach exabytes. These communities are also increasingly moving towards a global collaborative model where scientists routinely exchange a significant amount of data. The sheer volume of data and associated complexities associated with maintaining, transferring, and using them, continue to push the limits of the current technologies in multiple dimensions - storage, analysis, networking, and security. This thesis tackles the networking aspect of big-data science. Networking is the glue that binds all the components of modern scientific workflows, and these communities are becoming increasingly dependent on high-speed, highly reliable networks. The network, as the common layer across big-science communities, provides an ideal place for implementing common services. Big-science applications also need to work closely with the network to ensure optimal usage of resources, intelligent routing of requests, and data. Finally, as more communities move towards data-intensive, connected workflows - adopting a service model where the network provides some of the common services reduces not only application complexity but also the necessity of duplicate implementations. Named Data Networking (NDN) is a new network architecture whose service model aligns better with the needs of these data-oriented applications. NDN's name based paradigm makes it easier to provide intelligent features at the network layer rather than at the application layer. This thesis shows that NDN can push several standard features to the network. This work is the first attempt to apply NDN in the context of large scientific data; in the process, this thesis touches upon scientific data naming, name discovery, real-world deployment of NDN for scientific data, feasibility studies, and the designs of in-network protocols for big-data science

Supporting climate research using named data networking

Climate and other big data applications face substantial problems in terms of data storage, retrieval, sharing and management. While several community repositories and tools are available to help with climate data, these problems still persist and the community is actively looking for better solutions. In this project we apply NDN to support climate modeling applications. The information-centric nature of NDN, where content becomes a first class entity, simplifies many of the problems in this domain. NDN offers lightweight data publication, discovery and retrieval compared to IP-based solutions. However, introducing a new network architecture to a mature domain that routinely produces petabytes of datasets and a plethora of assorted tools to manipulate them, is a risky proposition. The advantages of NDN alone may not be sufficient to overcome the natural inertia. Our approach is to introduce NDN while carefully avoiding undue disruption to existing workflows. To that extent we employ a user interface that employs familiar filesystem operations to publish, discover and retrieve data, integrated with domain-specific translators that automatically convert and publish datasets as NDN objects. We outline the advantages of NDN in this application domain and the challenges we faced during the adaptation. We believe this is the first exercise in applying NDN in an existing, large, mature application domain