Data Mining & Data Warehousing

Data Mining In Other Scientific Applications

Introduction: Most scientific data analysis tasks tended to handle relatively small and homogeneous data sets. Such data were typically analyzed using a “formulate hypothesis, build model, and evaluate results” paradigm. In these cases, statistical techniques were appropriate and typically employed for their analysis.

Data collection and storage technologies have recently improved, so that today, scientific data can be amassed at much higher speeds and lower costs. This has resulted in the accumulation of huge volumes of high-dimensional data, stream data, and heterogenous data, containing rich spatial and temporal information. Consequently, scientific applications are shifting from the “hypothesize-and-test” paradigm toward a “collect and store data, mine for new hypotheses, confirm with data or experimentation” process. This shift brings about new challenges for data mining.

Vast amounts of data have been collected from scientific domains (including geosciences, astronomy, and meteorology) using sophisticated telescopes, multispectral high-resolution remote satellite sensors, and global positioning systems. Large data sets are being generated due to fast numerical simulations in various fields, such as climate and ecosystem modeling, chemical engineering, fluid dynamics, and structural mechanics. Other areas requiring the analysis of large amounts of complex data include telecommunications (Section 11.1.3) and biomedical engineering (Section 11.1.4).

In this section, we look at some of the challenges brought about by emerging scientific applications of data mining, such as the following:

Data warehouses and data preprocessing: Data warehouses are critical for information exchange and data mining. In the area of geospatial data, however, no true geospatial data warehouse exists today. Creating such a warehouse requires finding means for resolving geographic and temporal data incompatibilities, such as reconciling semantics, referencing systems, geometry, accuracy, and precision. For scientific applications in general, methods are needed for integrating data from heterogeneous sources (such as data covering different time periods) and for identifying events. For climate and ecosystem data, for instance (which are spatial and temporal), the problem is that there are too many events in the spatial domain and too few in the temporal domain. (For example, El Nino events occur only every four to seven years, and previous data might not have been collected as systematically as today.)Methods are needed for the efficient computation of sophisticated spatial aggregates and the handling of spatial-related data streams.

Mining complex data types: Scientific data sets are heterogeneous in nature, typically involving semi-structured and unstructured data, such as multimedia data and geo referenced stream data. Robust methods are needed for handling spatiotemporal data, related concept hierarchies, and complex geographic relationships (e.g., non- Euclidian distances).

 Graph-based mining: It is often difficult or impossible to model several physical phenomena and processes due to limitations of existing modeling approaches. Alternatively, labeled graphs may be used to capture many of the spatial, topological, geometric, and other relational characteristics present in scientific data sets. In graph modeling, each object to be mined is represented by a vertex in a graph, and edges between vertices represent relationships between objects. For example, graphs can be used to model chemical structures and data generated by numerical simulations, such as fluid-flow simulations. The success of graph-modeling, however, depends on improvements in the scalability and efficiency of many classical data mining tasks, such as classification, frequent pattern mining, and clustering.

Visualization tools and domain-specific knowledge: High-level graphical user interfaces and visualization tools are required for scientific data mining systems. These should be integrated with existing domain-specific information systems and database systems to guide researchers and general users in searching for patterns, interpreting and visualizing discovered patterns, and using discovered knowledge in their decision making.