technology, research and practice in mathematics education
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MERGA 33: Shaping thefuture of mathematics education
Technology, research and practice in mathematics educationBarry Kissane
The Mathematics Education Research Group of Australasia
+Outline
Technology in mathematics education What technology? Policy statements
Technology and research in mathematics education Trends over twenty years Big pictures and big ideas
Technology, research and practice in mathematics education (How) is practice informed by research? (How) might we do better?
+Clicker 1: Who are we today?
1. Classroom teacher (in a school)
2. Head of department (in a school)
3. Teacher educator (in a university)
4. Researcher (in a university)
5. Maths teacher (in a university)
6. Other
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+Technology in mathematics education
+Three roles for technology
Computational To provide answers to mathematical questions
Experiential To provide a means for students to interact with and
explore mathematical ideas not otherwise available, to provoke and support mathematical thinking
Influential To be considered as a significant factor when decisions are
made about the nature of the curriculum
+Policy positions on technology
ACARA Shape Paper on Australian Curriculum “An important consideration in the structuring of the curriculum
is to embed digital technologies so that they are not optional extras.” (p.9)
National Council of Teachers of Mathematics Position Paper “Technology is an essential tool for learning mathematics in the
21st century, and all schools must ensure that all their students have access to technology. Effective teachers maximize the potential of technology to develop students’ understanding, stimulate their interest, and increase their proficiency in mathematics. When technology is used strategically, it can provide access to mathematics for all students.” (2008)
+AAMT statements
AAMT Statement on the Use of Calculators and Computers for Mathematics in Australian Schools It is recommended that:
“1. All students have ready access to appropriate technology as a means both to support and extend their mathematics learning experiences” … (1996)
AAMT Communiqué on graphics calculators and school mathematics “There is a compelling case for the advantages offered to
students who use graphics calculators when learning mathematics. They are empowering learning tools, and their effective use in Australia’s classrooms is to be highly recommended”. (2000)
+Digital Education Revolution
Australian government initiative to provide laptops for students
Increased access to high speed broadband anticipated Mathematics Framing paper:
Digital technologies allow new approaches to explaining and presenting mathematics, as well as assisting in connecting representations and thus deepening understanding. The continuing evolution of digital technologies has progressively changed the work of mathematicians and school mathematics (consider the use of logarithm tables and the slide rule), and the curriculum must continue to adapt. Digital technologies are now more powerful, accessible and pervasive. (p.9)
+What technology for students?
Hand-held devices Four-function calculators Scientific calculators Graphics calculators CAS-enabled graphics
calculators Interactive devices
Casio ClassPad, TI-Nspire
PDA devices iPod Touch, iPhone, iPad
Computer software Spreadsheets Dynamic geometry
Cabri Geometry, Geometer’s SketchPad, GeoGebra, etc.
Statistics Fathom, TinkerPlots, etc …
iPod Touch, iPad The Internet
Worldwide web Learning online (HOTMaths) Maths by Email The Le@rning Federation Social networking, Web 2.0, etc.
+What technology for teachers?
Hand-held devices As for students With demonstration
versions Networked versions
Computer software As for students Demonstration software
E.g., Autograph
The Internet The Le@rning Federation Online learning
E.g., HOTMaths As for students
Teaching technology Interactive white boards Graphics tablets Audience response
devices (‘clickers’)
+Clicker 2: Mathematics, technology and me Which one best describes you?
1. I teach maths with technology and do some research related to technology
2. I teach maths with technology but don’t do research related to technology
3. I don’t teach maths with technology but some of my research is related to technology
4. I neither teach maths with technology nor do research related to technology
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+Computers, calculators, Internet, … It is clear that there are large differences between what
is ‘available’ to students and teachers Schools are differentially resourced
Some excellent software is expensive Staff have preferences as well
External constraints can be dominant (especially in senior secondary school) Graphics calculators’ portability, cost and exam
acceptability
Home Internet access is very high, and rising for many communities, but still SES differences
+A big picture 1990-2010
Seymour Papert in the early 1980’s observed that the computer laboratory was School’s defence against technology.
Graphics calculators were designed solely for mathematics education and broke down this defence (for many)
Software available on all computers (i.e. spreadsheets) began to be used too
Purpose-built software for mathematics education was developed
The Internet Laptop computers and home access to technology
+The big picture 2010-2030
+A personal opinion about graphics calculators My engagement with graphics calculators began in
1986, when it was clear that there was no more efficient way of ensuring access to technology in many, if not most, US schools.
It continues to be the case in 2010 that a technology that is individually affordable (to many), flexible, powerful, portable and acceptable to high-stakes exam authorities offers the best prospect of taking technology seriously and thinking of universal access. Despite its many limitations
This will not always be the case
+Technology examples?
Not really time Many are familiar
Graphics calculators CAS Interactive devices
Geometry Statistics Internet
+The Internet
There is a large and increasing number of opportunities for students to engage with mathematics on the web
+Some iPod examples
+Some more examples
+Technology and research in mathematics education
+Technology and research: A naïve question Teachers (and others) would like an answer to the naïve
question: “Does it work?” That is, if we use this technology with students, will they
learn mathematics (better)?
Yes? No? Of course, it is never that simple …
+
Does it work?
+
Why does it work?
+
Why doesn’t it work?
+
Why does it work only sometimes?
+
Why does it work only sometimes with my Year 10 class?
+
Why does it work only sometimes with Jane Smith’s Year 10 class?
+
Would it work with Jane Smith’s Year 10 class?
+
Would it work with Jane Smith’s Year 10 class in NSW?
+Technology and research: Does it work? It depends … on many things
The classroom The teacher The curriculum The student The technology itself
There is no panacea
+Changing research perspectives on technology in Australasia MERGA’s RIMEA series
1988-1991: Calculators and computers in teaching and learning of mathematics
1992-1995: ?? 1996-1999: Technology-assisted instruction in mathematics
education 2000-2003: Computers, multimedia and the Internet in
mathematics education; Calculators and computer algebra systems
2004-2007: Teaching and learning with technology: Realising the potential
2008-2011: ??
+Stages in research on technology Developmental work, drawing on research in various
disciplines Early empirical studies concerned with proof of concept Case studies Comparative studies involving quasi-experimental
designs Larger studies with randomised, controlled trials
+A balance of approaches
“While research in a wide range of areas could directly or indirectly facilitate the effective utilization of educational technology within our nations K-12 schools, much of the research that the panel believes to be most important falls into one of the the following three categories:
1. Basic research in various learning-related disciplines and fundamental work on various educationally related technologies;2. Early-stage research aimed at developing new forms of educational software, content and technology-enabled pedagogy; and3. Empirical studies designed to determine which approaches to the use of technology are in fact most effective. (PCAST, 1997, Executive Summary)” (p. 443)
Ferrini-Mundy, J. & Breaux, G.A. (2008) Research, policy and technology use. In Blume, Glendon W. & Heid, M. Kathleen (2008) Research on technology and the teaching and learning of Mathematics: Volume 2: Cases and perspectives. (pp 427-448) USA: Information Age, NCTM.
+Should technology have a role in school mathematics?
“In the Panel’s judgement, the principal goal of such empirical work should not be to answer the question of whether computers can be effectively used within the school. The probability that elementary and secondary education will prove to be the one information-based industry in which computer technology does not have a natural role would at this point appear to be so low as to render unconscionably wasteful any research that might be designed to answer this question alone. (PCAST, 1997, Section 8.3: Priorities for Future Research)” (p. 444)Ferrini-Mundy, J. & Breaux, G.A. (2008) Research, policy and technology use. In Blume, Glendon W. & Heid, M. Kathleen (2008) Research on technology and the teaching and learning of Mathematics: Volume 2: Cases and perspectives. (pp 427-448) USA: Information Age, NCTM.
+What might research offer us?
An opportunity to understand things better But rarely an unambiguous answer to important questions of
teaching and learning
An opportunity to explore the boundaries of relevance of a theoretical framework to understand practice
An opportunity to put (competing) theories to a test New phenomena to explore Most research projects generate as many fresh questions
as answers “Further research is needed to …”
+Problems with research on technology in particular A moving target, as the technology is changing (very rapidly), as Jim
Kaput remarked in 1992: “Anyone who presumes to describe the roles of technology in
mathematics education faces challenges akin to describing a newly active volcano — the mathematical mountain is changing before our eyes, with myriad forces operating on it and within it simultaneously.” (p. 515)
Unavoidable novelty effects Teacher effects Curriculum (including external examination) effects
especially in senior secondary school and undergraduate mathematics?
Time span (longitudinal research?) Up-scaling and generalisability problems
+The place of reviews of research For some of the foregoing reasons, research results
rarely (if ever) lead to uncomplicated, unequivocal ‘solutions’ to problems The gold standard of empirical scientific research, the
randomised experiment, is clearly unattainable in this field (yet)
… if in any branches of mathematics education …
So, systematic reviews of research are important, and meta-analyses even more important, to try to reconcile differences in findings
These are major undertakings (eg RIMEA)
+What does research tell us? Some sources RIMEA series
Every four years, focusing on Australasia
NCTM Handook of Research Key constructs
NCTM Research Syntheses volumes Systematic, structured compilations
MERGA conferences and journals Some recent highlights
+RIMEIA 2004-2007:Some big pictures Thomas, M. & Chinnappan, M. (2008) Teaching and
learning with technology: Realising the potential. In H. Forgasz, A. Barkatsas, A. Bishop, B. Clarke, S. Keast, T.S. Wee, T. S. & P. Sullivan (Eds.) Research in Mathematics Education in Australasia 2004-2007. (pp 165-193). Rotterdam: Sense Publishers.
“… a high level of enthusiasm from both students and teachers to embrace a variety of technologies …”
A focus on “… the crucial role of the teacher when employing technological tools…”
+Organising constructs
Affordances E.g., Presence of technology
Constraints Student or teacher instrumentation Time available Curriculum content
Pedagogical technology knowledge (PTK) “principles, conditions and techniques required to teach
mathematics through the technology” (p.167)
+Teacher variables
Metaphors for technology (Goos, Galbraith, Geiger, et al) Master Servant Partner Extension of self
Professional development variables Teacher confidence Technical expertise PTK
Use of CAS Teacher privileging CAS as a conceptual tool, not just a crutch
+Some big pictures?
“One factor that consistently needs attention is whether the success reported in studies can translate to teachers in general, or whether the research participants are exceptional in some ways.” (p. 170)
“Research and teaching community are enthused … but teachers need support and guidance in classroom implementation” Both pre-service and in-service. (p. 183)
Conflicting results regarding CAS
+A perspective of constructs
This recent major review of the field suggested a number of constructs as organisers of the research, evolved from collections of studies.
Rose Mary Zbiek, M. Kathleen Heid, Glendon W. Blume & Thomas P. Dick (2007) Research on technology in mathematics education: A perspective of constructs. In F. K. Lester Jr. (ed.) Second handbook of research on mathematics teaching and learning. (pp 1169-1207). USA: Information Age, NCTM.
+ Which constructs?
Technical and conceptual activities Cognitive tools Tools and mathematical activity
Externalised representation Mathematical fidelity Cognitive fidelity
Student-Tool relationships Instrumental genesis
+More constructs
Students and mathematical activity Exploratory activity Expressive activity Methods of working
Technology and practice Pedagogical fidelity (Teacher) privileging
Technology and curriculum: Constructs that capture the opportunities for change in curriculum facilitated by technology Representational fluency Mathematical concordance Amplifiers and reorganisers Sequencing and emphasis: Microprocedures and macroprocedures
+Research syntheses
Heid, M. Kathleen & Blume, Glendon W. (2008) Research on technology and the teaching and learning of Mathematics: Volume 1: Research syntheses. USA: Information Age, NCTM. Rational number Algebraic understanding Geometry Calculus Mathematical modelling Practice Equity
+Algebra
“Technology in conjunction with technology-based curricular approaches can effectively change the content and processes of school algebra.” (p. 97)
“Technology in conjunction with technology-based curricular approaches can affect the processes of mathematical activity in an algebraic setting. Many of these effects are related to the representational capacity of technology.” (p. 97)
“Technology in conjunction with technology-based curricular approaches can affect the acquisition of algebraic concepts and procedures” (p. 98)
Heid, M. Kathleen & Blume, Glendon W. (2008) Algebra and function development. In Heid, M. Kathleen & Blume, Glendon W. (Eds.) Research on technology and the teaching and learning of Mathematics: Volume 1: Research syntheses. (pp 55-108) USA: Information Age, NCTM.
+Geometry
“There is evidence that computer environments can support learning and teaching in geometry in new and dynamic ways, as well as complementing and enriching traditional strategies.” (p. 141)
“There is not yet a critical amount of research devoted to long-term teaching with regular use of DGS. Moreover there is currently a lack of computer-supported geometry teaching.” (p. 191)
“The computer provides a window on student’s [geometric] understandings.” (p.189)
“In a DGS, construction tasks induce the need to use geometrical knowledge.” (p. 190)
“DGS offers a new perspective in addressing the issue of the teaching and learning of proof.” (p. 190)
Hollebrands, K., Laborde, C. & Straser, R. (2008) Technology and the learning of geometry at the secondary level. In Heid, M. Kathleen & Blume, Glendon W. (Eds.) Research on technology and the teaching and learning of Mathematics: Volume 1: Research syntheses. (pp 155-205) USA: Information Age, NCTM.
+Probability and statistics
Statistics was not mentioned in the Research Syntheses publication, and Friel’s chapter emphasises the relative recency of attention to research on statistics education RIMEA 2004-2007 review also noted relative dearth of research
about statistics with technology in Australasia (at that time)
Research with educational software (such as Fathom and TinkerPlots) is relatively new, with results (case studies, design studies) informing conceptions of an appropriate curriculum.
Technology is an assumed part of the developing EDA conception of statistics, with a focus on understanding data.
Friel, S.(2008) The research frontier. In Blume, Glendon W. & Heid, M. Kathleen (Eds.) Research on technology and the teaching and learning of Mathematics: Volume 2: Cases and perspectives. (pp 279-331) USA: Information Age, NCTM.
+Teachers and technology
Survey research has provided some helpful information about secondary mathematics teacher use of technology and professional development needs The best recent example is: Goos & Bennison (2008) Surveying the technology
landscape: Teacher’s use of technology in secondary mathematics classrooms. Mathematics Education Research Journal, 20(3), 102-130.
Computers, graphics calculators and the Internet Clear effects of mandatory use of technology (graphics calculators) More use of technology in senior school than below Marginal use of computers and the Internet
Professional development is important and can be influential Bennison & Goos (MERJ, 2010) note that “effective integration remains
patchy”, with a number of teacher issues identified Thomas surveys (1995 & 2005) in NZ highlight access issues for
computers
+The Internet (and beyond)
There seems to be relatively little empirical research yet on the use of the Internet by students and teachers Internet as a source of information about mathematics seems to have
no place in the curriculum? (yet seems likely to be of interest to many students?)
There are very rapid changes in technology outside mathematics classrooms
Web 2.0 and the ubiquitous Internet Mobile phones with computer capabilities in an interconnected
world Podcasts and video
A curriculum that seems oblivious or impervious to these must seem increasingly quaint to students
How does research keep up?
+Undergraduate teaching
In many places, it seems that the use of technology in early undergraduate mathematics differs sharply from the use of technology in schools
Wood, L. (2008) University learners of mathematics. In H. Forgasz, A. Barkatsas, A. Bishop, B. Clarke, S. Keast, T.S. Wee, T. S. & P. Sullivan (Eds.) Research in Mathematics Education in Australasia 2004-2007. (pp 73-97). Rotterdam: Sense Publishers. “On computing tools, the majority of authors espouse the use of
professional software and hardware tools. Such as Excel, CAS and computers rather than teaching-only tools such as graphics calculators.” (p. 91)
“There is a distinct split between universities that favour computing tools for mathematics learning and those who work only with pen and paper.” (p.91)
+Proficiencies and technology
The draft Australian Curriculum – Mathematics identifies four ‘proficiencies’: Understanding Fluency Problem solving Reasoning
Teachers might reasonably expect to see clear guidance, advice and descriptions about the (different) role of technology in these
+The nature of the curriculum
There seems to be limited evidence of technology influencing the nature of the curriculum (at least in the Australian Curriculum drafts, in my personal opinion) Technology is mostly interpreted as ‘pedagogy’ and thus the
prerogative of the teacher?
Computation is recognised, and there is encouragement to use ‘available technology’ to change the teaching and learning experience
Coherence of teaching, learning and assessment is worthy of closer research, as it seems highly likely that what is used in assessment is likely to determine what is generally used for teaching and learning.
+K-10 draft, Australian Curriculum Information and communication technologies (ICT)
allow students to solve problems and perform tasks that previously have been onerous. Calculators of all types from the simple four operations versions to the more complex graphical and CAS calculators allow students to make calculations, draw graphs and interpret data in ways that previously have not been possible. There are spreadsheets, dynamic geometry programs and other software that can engage students and promote understanding of key concepts. It is expected that mathematics classrooms will make use of all available ICT in teaching and learning situations. [ACARA, 2010; emphasis added]
+11-12 draft, Australian curriculum The Shape of the Australian Curriculum – Mathematics
states that available technology should be used for teaching and learning situations. Technology can include computer algebra systems, graphing packages, financial and statistical packages and dynamic geometry. These can be implemented through either a computer or calculator.
Technology can aid in developing skills and allay the tedium of repeated calculations. For example a technology can be used to complete recursive calculations.
The decision about using technology in assessment programs is not within the province of the curriculum, jurisdictional assessment agencies will make that decision.
+Adding-on technology?
Fey, J.T., Hollenbeck, R.M. & Wray, J.A. (2010) Technology and the mathematics curriculum. In Reys, B.J., Reys, R.E. & Rubenstein, R. NCTM 72nd Yearbook: Mathematics curriculum. (pp 41-49). Reston, VA: NCTM offered an opinion on this question: Curriculum specialists and other interested parties should examine
objectives to determine whether technology can enhance students’ learning of mathematics. However, technology should not be an add-on to curricula. Using technology to cover topics that are just as accessible through other approaches may actually interfere with learning and undermine the benefits of technology. Given the urgency of providing strong mathematical preparation for students who will enter and live in a technologically sophisticated society and workplace, such study and experimentation by all involved in the enterprise of mathematics teaching should be a high priority for our field. (2010, p.48) (Emphasis added.)
+Some examples of curriculum influence? E.g., changing the emphasis in statistics from
mathematical statistics to data analysis, using real data and real problems, using suitable technology tools
E.g., approaches to probability beyond the formal classicist approach (in terms of sample spaces and equally likely outcomes, sets and combinatorics); study of ‘risk’
E.g., numerical approaches to ‘calculus’ problems such as finding relative extrema or numerical solutions to differential equations
E.g., Focus on construction and interpretation of integrals, rather than methods of integration, in an age of CAS
+Some more examples
E.g., explorations with geometric software to encourage and motivate conjecturing, reasoning and proof
E.g., some focus on numerical solution of equations rather than only on exact solutions of equations
E.g., use of reducible interest (which is what occurs in practice) rather than simple and compound interest (which usually don’t occur in practice)
Emphasis in the draft Australian Curriculum seems to focus on using technology to teach the same curriculum to which we have become accustomed … a form of retrofitting … rather than reconsider the scope and sequence of the curriculum in the light of available technologies This is of course an opinion, not an empirical finding
+Technology, research and practice in mathematics education
+Research and practice
How does research influence practice? In general, not only for the particular case of technology
What are the problems? How might we strengthen the links?
+A litmus test?
Julie is teaching her Maths 2D class next semester, starting a unit on calculus with a group of students not in the strongest stream. She has been teaching for six years now and is a competent user of technologies. Should students use the CAS calculator? Why? How? For what? Will some computer software be useful? Which? How should
she use it? Could the Internet be useful here? How? For what? Could her Interactive White Board be used? How? Why?
What will research tell her about such things? Where should she look?
+Clicker 4: Consulting researchThink of some maths you have taught to students recently with technology. Which of the following best describes you?
1. I consulted a research source for advice before I started.
2. I had previously consulted research, so didn’t need to do so again.
3. I did not consult any research.
4. I haven’t taught maths to studentsrecently with technology.
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+Possibility 1: Practitioners accessing researchers Attend the MERGA conference (in their home city) Attend the joint AAMT-MERGA conference(s)
In Alice Springsnext July
Interrogate the MERGA website for conference or journal publications Obtain published research advice
Research journals are usually not written for the audience of teachers Very expensive and inaccessible in most schools Interpretations of ‘impact’ within ERA focus on research colleagues not
colleagues in schools “Voices from the field” in MERJ is a welcome initiative
+Possibility 2: Researchers advising practitioners Researchers can advise practitioners directly
“What research says” monographs? Earlier research syntheses published by NCTM 67th NCTM Yearbook: technology-supported mathematics learning
environments (2005) is a good example Association of Mathematics Educators (Singapore) Handbooks
Write advice papers based on research in journals for teachers It is hard to write these; partly because research findings often do
not readily translate to practice Not many people try to do this, as the rewards are few
Conduct targeted conferences (eg ACER conference 2010) for the purpose Impact unavoidably limited to those who can attend
+Clicker 5: Advising practitioners
In the last two years, have you submitted a paper based on your research to a publication meant for maths teachers?
1. Yes, and it was accepted
2. Yes, but it was rejected
3. No
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+Possibility 3: Materials development Classroom materials and curricula can be developed
following classroom-based research CAS-CAT project TinkerPlots, Geometer’s SketchPad materials Hillary Shuard project Calculator Aware Numeracy materials (Some) calculator manufacturer materials are based on work in
schools MATHS300 software
Materials themselves can be researched Even trialing seems rare for Australian school textbooks? UCSMP experience
+Possibility 4: Professional development Pre-service teacher education
Informed by research (eg Goos, Stillman & Vale’s Teaching Secondary School Mathematics: Research and Practice for the 21st Century)
Limited short-term impact on the field, as most teachers are already teaching!
Teacher conferences Seems rare for research to be the basis of presentations? Rare for researchers to see these as important? Even rarer for their institutions to do so in the world of ERA?
Teacher courses (Eg 2008 Summer School) Happen rarely and impact on only a few?
+Clicker 6: Teacher meetings
In the past year, have you attended a conference or meeting of teachers inorder to discuss your research?
1. Yes
2. No
3. I’ve not been involved in research in the past year.
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+Possibility 5: Researchers and practitioners working together Action research projects
Eg, AGQTP, ASSISTM
Classroom-based research generally Teaching experiments, case studies, field trials Funding? Time-span?
Queensland team (Goos, Geiger, Renshaw, Galbraith, …) is a very good example We need more good examples
+Clicker 7: Working togetherIn the past year, have you worked in a school with a team of colleagues on a research project?
1. Yes; I am a school teacher member of the research team
2. Yes; I am a member of the research team, but not a school teacher
3. No; although my students were involved in a research project
4. No
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+Possibility 6: Web-based support ACARA intentions are to provide significant online advice and
support to teachers How can advice informed by research on technology be best included in
that? Who will do it? Especially in light of the limited inclusion of technology into the curriculum
itself to date
MERGA website is outstanding, although the materials are not written with practice in mind
NCETM example in the UK seems to have much to commend it. Here is an example about Interactive White Boards. Is there scope for an Australian version? Very significant funding is needed Not only about technology, of course
+Concluding remarks
+If …
The technology is designed to capture important mathematical ideas faithfully; and
It is improved with the aid of suitable research with students; and
The curriculum is written and assessed on the assumption that technology is available; and
Curriculum materials and tasks have been developed accordingly; and
The teacher is adequately supported to use the technology confidently and well in the classroom; then
It will ‘work’
+Bringing it all together: some final observations There is a rich resource of research on technology already available …
with many gaps It is already clear that technology has much to offer While the world of technology itself keeps changing rapidly
Much of the research is not written directly for teachers Focus of some research is on teacher practices, recognising that what
happens in classrooms is of great importance, not only the technology itself
Professional development is a direct object of study Building partnerships between research and practice is a critical part of
making joint progress … so, finally, what is the relationship between research and practice…?
+Research and practice
Practice
Research
+Clicker 8: Did you like that picture?
1. Yes
2. No
3. I didn’t understand it, so I can’t tell.
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+Thank you
B.Kissane@Murdoch.edu.au
http://wwwstaff.murdoch.edu.au/~kissane
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