Spatial Data Infrastructure (GEOM90015)

Graduate courseworkPoints: 12.5On Campus (Parkville)

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Overview

Availability
Semester 2
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AIMS

In this subject, students will learn about the principles, concepts and design strategies used in the development of Spatial Data Infrastructure (SDI) as an enabling platform to facilitate multi-sourced data and service discovery, access, integration and use. An example of SDI is the land titles system and the tools used to maintain and interrogate it. Emphasis will be placed on both technological and institutional factors that facilitate the development of SDIs. Students will examine related disciplines such as land and marine administration as well as technical areas such as interoperability, web-mapping and web-delivery to better meet sustainable development objectives. This subject is of particular relevance to students who want to pursue a career in spatial data management, land administration, but is also relevant to a range of geomatic engineering disciplines that use and produce large spatial datasets for decision-making in support of sustainable development.

The subject partners with other subjects on spatial data management, spatial data analysis and spatial data visualization, and is of particular relevance to people wishing to establish a career in the spatial information industry, the environmental or planning industry.

INDICATIVE CONTENT

SDI concepts and theory, current SDI initiatives, SDI development strategies and development models; SDI as an enabling platform, SDI and Spatially Enabled Government and Society, SDI and partnership approaches, financing and capacity building, challenges for developed and developing countries, capacity building, marine SDI and seamless SDI, policy and privacy Issues, SDI and land administration, metadata, standards and clearinghouses, SDI application areas, and SDI implementation and benchmarking.

Intended learning outcomes

On completion of this subject the student is expected to:

  • SILO 1. Describe the core principles of data integration and sharing for infrastructure engineering, delivery and operation;
  • SILO 2. Identify the necessary components required for the development of data sharing and integration platforms for infrastructures including technical and institutional arrangements;
  • SILO 3. Apply a range of technologies for developing data integration and sharing platforms;
  • SILO 4. Analyse and evaluate data integration and sharing platforms.

Generic skills

On successful completion students should have:

  • Ability to undertake problem identification, formulation, and solution
  • Understanding of social, cultural, global, and environmental responsibilities and the need to employ principles of sustainable development
  • Ability to communicate effectively with the engineering team and with the community at large.

Last updated: 27 June 2024

Eligibility and requirements

Prerequisites

Note: the following subject/s can also be taken concurrently (at the same time)

Code Name Teaching period Credit Points
GEOM90008 Spatial Data Management
Semester 2 (On Campus - Parkville)
Semester 1 (Dual-Delivery - Parkville)
 12.5

Corequisites

None

Non-allowed subjects

Code Name Teaching period Credit Points
GEOM30014 Integrating Digital Infrastructure
Semester 2 (On Campus - Parkville)
 12.5

Recommended background knowledge

An understanding of spatial data and relevant processes and service delivery concepts.

It is advisable that students undertake this subject in their final year of study.

Inherent requirements (core participation requirements)

The University of Melbourne is committed to providing students with reasonable adjustments to assessment and participation under the Disability Standards for Education (2005), and the Assessment and Results Policy (MPF1326). Students are expected to meet the core participation requirements for their course. These can be viewed under Entry and Participation Requirements for the course outlines in the Handbook.

Further details on how to seek academic adjustments can be found on the Student Equity and Disability Support website: http://services.unimelb.edu.au/student-equity/home

Last updated: 27 June 2024

Assessment

DescriptionTimingPercentage

One group major assignment of a workload equivalent to 3000 words per student (50%), and a team presentation of 15 minutes (10%). Addressing Intended Learning Outcomes (iloS) 1-4.

  • 3000 words (each)
Due at the end of Week 2 of the examination period60%

Individual assessment: One selected topic oral presentation. 20 minutes and discussion, 20 hours of work. Addressing ILOs 1,2 & 4.

  • 20 minutes
During the teaching period20%

A schedule of five online quizzes of 10 minutes in duration each, to be delivered during class-time over the course. Addressing ILOs 2 & 3.

  • 50 minutes
During the teaching period20%

Last updated: 27 June 2024

Dates & times

  • Semester 2
    CoordinatorAbbas Rajabifard
    Mode of deliveryOn Campus (Parkville)
    Contact hours48 hours (Lectures: 24 hours; Practicals: 24 hours)
    Total time commitment200 hours
    Teaching period24 July 2023 to 22 October 2023
    Last self-enrol date 4 August 2023
    Census date31 August 2023
    Last date to withdraw without fail22 September 2023
    Assessment period ends17 November 2023

    Semester 2 contact information

    Professor Abbas Rajabifard

    abbas.r@unimelb.edu.au

Time commitment details

200 hours

Last updated: 27 June 2024

Further information

  • Texts

    Prescribed texts

    1. Crompvoets, J., Rajabifard, A., van Loenen, B. and Delgado Fernandez, T. (2008), Multi-view Framework to Assess SDIs
    2. Rajabifard, A. (2007), Towards a Spatially Enabled Society. The University of Melbourne Press
    3. Williamson, I.P, Rajabifard, A. and Feeney, M.-E. (2003). Developing Spatial Data Infrastructures: From Concept to Reality. Taylor and Francis
  • Subject notes

    LEARNING AND TEACHING METHODS

    The subject is based principally on content that has been developed from industry experience in designing, developing and implementing SDIs. This will be supplemented by guest presentations and seminars from industry professionals. A computer laboratory will be used to explore potential technological tools and different lab exercise that can be used to learn how to design and use different components related to SDIs. In the tutorials, students will work in groups to apply theory gained in the lectures to a real world industry case study. This learning will enable students to consolidate their knowledge in a practical and relevant way. Within their groups students will also prepare and present a minor research project on an affiliated topic of their interest selected from an extensive list.

    INDICATIVE KEY LEARNING RESOURCES

    The subject will utilise different sources (books, journal papers, conference papers, etc.) mostly available through the website for the Centre for SDIs and Land Administration, Department of Infrastructure Engineering, The University of Melbourne (www.csdila.unimelb.edu.au). The subject in particular will utilise the following books:

    • ‘Developing Spatial Data Infrastructures: from concept to reality’, Taylor and Francis, 2003 UK, edited by Ian Williamson, Abbas Rajabifard and Mary-Ellen F. Feeney,
    • ‘Towards a Spatially Enabled Society’, The University of Melbourne 2007, edited by Abbas Rajabifard, The University of Melbourne.
    • ‘Multi-view Framework to Assess SDIs’, edited by Joep Crompvoets, Abbas Rajabifard, Bastiaan van Loenen and Tatiana Delgado Fernandez, 2008.
    • and related scientific journal or conference publications (particularly from GSDI and INSPIRE conferences) will be also utilised.

    CAREERS / INDUSTRY LINKS

    Presenters from relevant government and private agencies will present guest lectures and seminars. Real-world examples of SDIs will be used as case studies.

  • Related Handbook entries

    This subject contributes to the following:

    TypeName
    CourseDoctor of Philosophy - Engineering
    CoursePh.D.- Engineering
    CourseMaster of Philosophy - Engineering
    Specialisation (formal)Spatial
  • Available through the Community Access Program

    About the Community Access Program (CAP)

    This subject is available through the Community Access Program (also called Single Subject Studies) which allows you to enrol in single subjects offered by the University of Melbourne, without the commitment required to complete a whole degree.

    Please note Single Subject Studies via Community Access Program is not available to student visa holders or applicants

    Entry requirements including prerequisites may apply. Please refer to the CAP applications page for further information.

    Additional information for this subject

    Subject coordinator approval required

  • Available to Study Abroad and/or Study Exchange Students

    This subject is available to students studying at the University from eligible overseas institutions on exchange and study abroad. Students are required to satisfy any listed requirements, such as pre- and co-requisites, for enrolment in the subject.

Last updated: 27 June 2024