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Peter Fox Data Science – CSCI/ERTH/ITWS-4350/6350 Week 11, November 12, 2013

Academic Basis for Data and Information Science, Data Models, Schema, Data Tools and Data as Service Paradigms. Peter Fox Data Science – CSCI/ERTH/ITWS-4350/6350 Week 11, November 12, 2013. Contents. Reading Informatics Data models Schema Tools Markup languages Data as service

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Peter Fox Data Science – CSCI/ERTH/ITWS-4350/6350 Week 11, November 12, 2013

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  1. Academic Basis for Data and Information Science, Data Models, Schema, Data Tools and Data as Service Paradigms Peter Fox Data Science – CSCI/ERTH/ITWS-4350/6350 Week 11, November 12, 2013

  2. Contents • Reading • Informatics • Data models • Schema • Tools • Markup languages • Data as service • How are the projects going?

  3. Reading? • Introduction to Data Management • Changing software, hardware a nightmare for tracking scientific data (and Parts I, II and III) • Overview of Scientific Workflow Systems, Gil (AAAI08 Tutorial) • Comparison of workflow software products, Krasimira Stoilova ,Todor Stoilov • Scientific Workflow Systems for 21st Century, New Bottle or New Wine? Yong Zhao, Ioan Raicu, Ian Foster

  4. Definitions (revisited) • Data - are pieces of <x> that represent the qualitative or quantitative attributes of a variable or set of variables. • Data (plural of "datum", which is seldom used) - are typically the results of measurements and can be the basis of graphs, images, or observations of a set of variables. • Data - are often viewed as the lowest level of abstraction from which information and knowledge are derived

  5. Definitions ctd. • Information • Representations (of facts? data?) in a form that lends itself to human use • Knowledge • …. Meaning – but watch how this may become so very important

  6. Data-Information-Knowledge Ecosystem Producers Consumers Experience Data Information Knowledge Creation Gathering Presentation Organization Integration Conversation Context

  7. Mind the gap • As we aim to use modern technology to advance data science: • There is often a gap between science and the underlying infrastructure and technology that is available • Informatics - information science includes the science of (data and) information, the practice of information processing, and the engineering of information systems. Informatics studies the structure, behavior, and interactions of natural and artificial systems that store, process and communicate (data and) information. It also develops its own conceptual and theoretical foundations. Since computers, individuals and organizations all process information, informatics has computational, cognitive and social aspects, including study of the social impact of information technologies. Wikipedia. • Cyberinfrastructure is the new research environment(s) that support advanced data acquisition, data storage, data management, data integration, data mining, data visualization and other computing and information processing services over the Internet.

  8. A moment of history • In the late 1950’s (actually around 1957-1958) the modern informatics term was coined • Existed for a while but then split into library science and computer science and developed their own fields, became disconnected • Now coming back to be relevant to science • Informatics IS NOT just having a scientist work with an “IT/ICT” person

  9. Advertisement • Spring 2014 – Xinformatics • See last year: http://tw.rpi.edu/web/course/Xinformatics/2013

  10. Library science • Curates the artifacts of knowledge • Organizes and manages them for consumers • Cataloging and classification • Preservation • ‘maintaining or restoring access to artifacts, documents and records through the study, diagnosis, treatment and prevention of decay and damage’ (wikipedia) • Digital age • Curation and preservation

  11. Cognitive Science • Cognitive science is an interdisciplinary study of the mind and intelligence • It operates at the intersection of psychology, philosophy, computer science, linguistics, anthropology, and neuroscience. • Of relevance for data and information science are three significant theoretical underpinnings • mental representation, • the nature of expertise, • and intuition • Very relevant to model, data/metadata choice

  12. Social Science • Branch of humanities • Especially as it relates to networks of scientists • Exploits sociology of groups, teams • Cultural norms as well as discipline norms • Modes of what and how rewards are given • Between those who produce and those who consume data (and information) • More

  13. Information theory • Semiotics, also called semiotic studies or semiology, is the study of sign processes (semiosis), or signification and communication, signs and symbols, into three branches: • Syntactics: Relation of signs to each other in formal structures • Semantics: Relation between signs and the things to which they refer; their denotata • Pragmatics: Relation of signs to their impacts on those who use them

  14. Note: we have theories for… • Knowledge -> various forms of logic(s) • Information (Shannon, Weaver, Peirce…) • But not ‘Data’ (except for …) • < reading for this week > sneak peek… • http://tw.rpi.edu/web/node/3605 (Mealy 1967) • http://tw.rpi.edu/web/node/3606 (Wickett et al.)

  15. Mealy’s Introduction • “We do not, it seems, have a very clear and commonly agreed upon set of notions about data-either what they are, how they should be fed and cared for, or their relation to the design of programming languages and operating systems. This paper sketches a theory of data which may serve to clarify these questions. It is based on a number of old ideas and may, as a result, seem obvious. Be that as it may, some of these old ideas are not common currency in our field, either separately or in combination; it is hoped that rehashing them in a somewhat new form may prove to be at least suggestive.”

  16. Three elements and connections • Relations • Data Maps • Access Functions • The data itself • Procedures • Storage and representation • Descriptors

  17. Wickett et al… • “Heterogeneous digital data that has been produced by different communities with varying practices and assumptions, and that is organized according to different representation schemes, encodings, and file formats, presents substantial obstacles to efficient integration, analysis, and preservation. This is a particular impediment to data reuse and interdisciplinary science. An underlying problem is that we have no shared formal conceptual model of information representation that is both accurate and sufficiently detailed to accommodate the management and analysis of real world digital data in varying formats. Developing such a model involves confronting extremely challenging foundational problems in information science. “

  18. Premise Context Experience Data Information Knowledge Creation Gathering Presentation Organization Integration Conversation 18

  19. 1. Assume context free • Content and Structure • D=f(x;p) • D=data, f=transduction function, x=thing, p=parametric dependence (e.g. time of transduction) • HAVE – Syntax • DO NOT HAVE - Semantics – no meaning without context • OR - Pragmatics – no use without meaning?? • What about - Uncertainty, quality, bias (error) – none without context?

  20. 2. Assume minimal context • Minimal = incomplete? • E.g. know instrument but not when, or of what • E.g. know what but not how • Partial uncertainty? Conditional entropy? • Constructive induction?

  21. Pulling things over from Informatics Context Experience Data Information Knowledge Creation Gathering Presentation Organization Integration Conversation 21

  22. Information Models • Conceptual models, sometimes called domain models, are typically used to explore domain concepts • High-level conceptual models are often created as part of initial requirements envisioning efforts as they are used to explore the high-level static business or science or medical structures and concepts.

  23. (Information) Architecture • Definition: • “is the art of expressing a model or concept of information used in activities that require explicit details of complex systems” (wikipedia) • “… I mean architect as in the creating of systemic, structural, and orderly principles to make something work - the thoughtful making of either artifact, or idea, or policy that informs because it is clear.” Wuman

  24. Data Models • Conceptual data models, sometimes called domain models, are typically used to explore domain concepts • Conceptual data models are often created as the precursor to logical data models or as alternatives to them. • http://en.wikipedia.org/wiki/Data_modelling

  25. Observation and Measurement

  26. Mapping model to geochemistry

  27. Specimen Model

  28. Conceptual model

  29. Logical model

  30. Physical model

  31. Conceptual model – shoreline photos

  32. Logical model – shoreline photos

  33. However as a consumer • Do you ever really see these data models? • What’s the most common form of making data available to others? • What’s the most common means? Second most common?

  34. Example XML <?xml version="1.0" encoding="ISO-8859-1"?> <shiporder orderid="889923" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:noNamespaceSchemaLocation="shiporder.xsd"> <orderperson>John Smith</orderperson> <shipto> <name>Ola Nordmann</name> <address>Langgt 23</address> <city>4000 Stavanger</city> <country>Norway</country> </shipto> <item> <title>Empire </title> <note>Special Edition</note> <quantity>1</quantity> <price>10.90</price> </item> <item> <title>Hide your heart</title> <quantity>1</quantity> <price>9.90</price> </item> </shiporder>

  35. Very simple schema <?xml version="1.0" encoding="ISO-8859-1" ?> <xs:schema xmlns:xs=http://www.w3.org/2001/XMLSchema> <xs:element name="shiporder"> <xs:complexType> <xs:sequence> <xs:element name="orderperson" type="xs:string"/> <xs:element name="shipto"> <xs:complexType> <xs:sequence> <xs:element name="name" type="xs:string"/> <xs:element name="address" type="xs:string"/> <xs:element name="city" type="xs:string"/> <xs:element name="country" type="xs:string"/> </xs:sequence> </xs:complexType> </xs:element> <xs:element name="item" maxOccurs="unbounded"> <xs:complexType> <xs:sequence> <xs:element name="title" type="xs:string"/> <xs:element name="note" type="xs:string" minOccurs="0"/> <xs:element name="quantity" type="xs:positiveInteger"/> <xs:element name="price" type="xs:decimal"/> </xs:sequence> </xs:complexType> </xs:element> </xs:sequence> <xs:attribute name="orderid" type="xs:string" use="required"/> </xs:complexType> </xs:element> </xs:schema>

  36. Markup Languages • Reminder: • Mixes data and metadata, and yes, information • Tag structure does not always model the underlying data structure • Modeling the XML itself, i.e. the schema is another task • Does have the potential benefit that it is more for use than storage • Parsing the file: • Incomplete versus complete tags • Empty or optional fields

  37. Data tools (just a few) • Models • http://www.datamodel.org/ • MSDN: http://msdn.microsoft.com/en-us/library/bb399249.aspx • Schema • The Schematron differs in basic concept from other schema languages in that it not based on grammars but on finding tree patterns in the parsed document. This approach allows many kinds of structures to be represented which are inconvenient and difficult in grammar-based schema languages. If you know XPath or the XSLT expression language, you can start to use The Schematron immediately. • http://www.schematron.com/

  38. Markup Language tools • Any context-sensitive editor • XMLSpy, XML Notepad, XML Editor, oXygen

  39. Data as Service • Modern internet architectures allow for • Service oriented architectures • Resource oriented architectures • Why is this important for data models, schema, etc. • Hides/ obscures underlying model, schemas • Service interfaces are often a poor/ hybrid match for underlying models • UML and ISO 19xxx family of standards, e.g. 19135 are changing the landscape • Mature in certain settings.

  40. Open Geospatial Consortium • Web Feature Service (WFS) • http://www.opengeospatial.org/standards/wfs • support INSERT, UPDATE, DELETE, LOCK, QUERY and DISCOVERY operations on geographic features using HTTP as the distributed computing platform • Built on Geographic Markup Language (GML) • Tutorial • http://docs.codehaus.org/display/MAP/WFS+Tutorial

  41. WFS examples

  42. Open Geospatial Consortium • Web Mapping Service (WMS) • http://www.opengeospatial.org/standards/wms • produces maps of spatially referenced data dynamically from geographic information ("map" is a portrayal of geographic information as a digital image file suitable for display on a computer screen). A map is not the data itself. WMS-produced maps are generally rendered in a pictorial format such as PNG, GIF or JPEG, or occasionally as vector-based graphical elements in Scalable Vector Graphics formats. • http://www.intl-interfaces.com/cookbook/WMS/ • http://oceanesip.jpl.nasa.gov/esipde/guide.html

  43. Open Geospatial Consortium • Web Coverage Service (WCS) • http://www.opengeospatial.org/standards/wcs • supports electronic interchange of geospatial data as "coverages" – that is, digital geospatial information representing space-varying phenomena

  44. Open Geospatial Consortium • Sensor Observation Service (SOS) • http://www.opengeospatial.org/standards/sos • SWE Common • http://www.opengeospatial.org/projects/groups/swecommonswg • Get_capabilities

  45. IVOA (www.ivoa.net) • Simple Image Access Protocol • http://ivoa.net/Documents/SIA/20091008/PR-SIA-1.0-20091008.pdf • This specification defines a protocol for retrieving image data from a variety of astronomical image repositories through a uniform interface. The interface is meant to be reasonably simple to implement by service providers. A query defining a rectangular region on the sky is used to query for candidate images. • The service returns a list of candidate images formatted as a VOTable. For each candidate image an access reference URL may be used to retrieve the image. Images may be returned in a variety of formats including FITS and various graphics formats. Referenced images are often computed on the fly, e.g., as cutouts from larger images.

  46. IVOA (www.ivoa.net) • E.g. Simple Spectrum Access Protocol • http://ivoa.net/Documents/REC/DAL/SSA-20080201.pdf • The Simple Spectrum Access (SSA) Protocol (SSAP) defines a uniform interface to remotely discover and access one dimensional spectra. SSA is a member of an integrated family of data access interfaces altogether comprising the Data Access Layer (DAL) of the IVOA. • SSA is based on a more general data model capable of describing most tabular spectrophotometric data, including time series and spectral energy distributions (SEDs) as well as 1-D spectra; however the scope of the SSA interface as specified in this document is limited to simple 1-D spectra, including simple aggregations of 1-D spectra.

  47. Discussion • Theoretical concepts- do we have any hope? • Data models – could you develop one? • Forms of Schema? • Service paradigms? • Relation to data management?

  48. Summary • Informatics in relation to data science • Discuss? • Data models and schema and the tools that go with them are plentiful • Modern use of XML and specific markup languages obscure the underlying data structure (physical and logical) but have other advantages • Data as service carry this to another level

  49. What is next • Next week – watch your email. • Next lecture (#12) – Nov. 26th. • Webs of data, data on the web, deep Web, data discovery, data citation • Reading: • See web site for this week

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