Robotics within the teaching of Problem-Solving

Volume/Issue:  Vol 7, Issue 1

Date:Sunday, 1 June, 2008

Journal Name: ITALICS

Author(s)

Scott Turner

Gary Hill

Abstract
This paper considers the experiences of teaching on a module where problem-solving is taught first, then programming. The main tools for the problem-solving part, alongside two problem-solving approaches, are tasks using Mindstorm (LEGO, Denmark) robot kits. This is being done as a foundation step before the syntax of a language (Java) is taught to enable a Graphical User Interface (GUI) emulation of a previous robot problem. Results of student evaluation and feedback will be presented and the use of two simulators will be considered.

Full paper available at: https://www.heacademy.ac.uk/robotics-within-teaching-problem-solving or PDF version https://www.heacademy.ac.uk/sites/default/files/ital.7.1h.pdf

All opinions in this blog are the Author's and should not in any way be seen as reflecting the views of any organisation the Author has any association with.

Problems First, Second and Third DOI: 10.4018/ijqaete.2014070104

A paper has recently been published in International Journal of Quality Assurance in Engineering and Technology Education on problem-solving and programming by two members of the Department of Computing and Immersive Technologies, University of Northampton.

Problems First, Second and Third. 

Gary Hill and Scott Turner
DOI:  10.4018/ijqaete.2014070104

Abstract
This paper considers the need to focus initial programming education on problem-solving, prior to the teaching of programming syntax and software design methodology. The main vehicle for this approach is simple Lego based robots programmed in Java, followed by the programming of a graphical representation/simulation to develop programming skills. Problem solving is not trivial (Beaumont & Fox, 2003) and is an important skill, central to computing and engineering. The paper extends the authors earlier research on problems first and problem solving (Hill & Turner, 2011) to further emphasise the importance of problem-solving, problem based learning and the benefits of both physical and visual solutions. An approach will be considered, illustrated with a series of problem-solving tasks that increase in complexity at each stage and give the students practice in attempting problem-solving approaches, as well as assisting them to learn from their mistakes. Some of the problems include ambiguities or are purposely ill-defined, to enable the student to resolve these as part of the process. The benefits to students will be discussed including students' statements that this approach, using robots, provides a method to visually and physically see the outcome of a problem. In addition, students report that the method improves their satisfaction with the course. The importance of linking the problem-solving robot activity and the programming assignment, whilst maintaining the visual nature of the problem, will be discussed, together with the comparison of this work with similar work reported by other authors relating to teaching programming using robots (Williams, 2003). In addition, limitations will be discussed relating to the access to the physical robots and the alternative attempts to simulate the robots using three options of, Microsoft Robotics Studio (MSRS), Lego Mindstorms and Greenfoot simulators.

• Hill, G. and Turner, S. J. (2014) Problems First, Second and Third. International Journal of Quality Assurance in Engineering and Technology Education (IJQAETE). 3(3), pp. 88-109. ISSN: 2155-496 DOI: 10.4018/ijqaete.2014070104

To read a preview of the paper go to: http://www.igi-global.com/viewtitlesample.aspx?id=117560&ptid=91662&t=Problems%20First,%20Second%20and%20Third



All opinions in this blog are the Author's and should not in any way be seen as reflecting the views of any organisation the Author has any association with.

Robots and Problem-solving or is it Computational Thinking

Confession time, this has been a research interest for me, along with a number of colleagues, since around 2005. It started with undergraduate students - investigating teaching and developing problem solving skills as a first step developing programming skills through the use of LEGO-based robots and graphics based programming for undergraduate students. The main vehicle for developing the problem-solving skills has been LEGO Mindstorms robotics kits and series of gradually more challenging robot-based tasks.

Lawhead et al (2003) stated that robots “…provide entry level programming students with a physical model to visually demonstrate concepts” and “the most important benefit of using robots in teaching introductory courses is the focus provided on learning language independent, persistent truths about programming and programming techniques. Robots readily illustrate the idea of computation as interaction”. Synergies can be made with our work and those one on pre-object programming and simulation of robots for teaching programming as a visual approach to the teaching of the widely used programming language  Java.

The main benefits that the students stated of this approach was they  believe robots provide a method to visually and physically see the outcome of a problem. The approach taken the module has been visually-orientated. The appropriateness of this seems to be borne out by the student comments. Student satisfaction  for a module based around this approach is over 92%. One of the comments made was that the linking of the problem-solving robot task and the programming assignment was liked. This feedback is similar to that reported by other authors when teaching programming using robots (Williams et al, 2003).  There is enough scope in this approach to have different levels of complexity/functionality within an assignment task offering a basic ‘pass’ level for a particular task, but also the scope for those students that desire more of a challenge.




Reference
Lawhead PB, Bland CG, Barnes DJ, Duncan ME, Goldweber M, Hollingsworth RG,
Schep M (2003), A Road Map for Teaching Introductory Programming Using
LEGO Mindstorms Robots SIGCSE Bulletin, 35(2): 191-201.
Williams AB (2003) The Qualitative Impact of Using LEGO MINDSTORMS Robot
to Teach Computer Engineering IEEE Trans. Educ. Vol. 46 pp 206.


Publications

• Hill, G. and Turner, S. J. (2014) Problems First, Second and Third. International Journal of Quality Assurance in Engineering and Technology Education (IJQAETE). 3(3), pp. 88-109. ISSN: 2155-496  DOI: 10.4018/ijqaete.2014070104
• Turner S (2014) "Greenfoot in Problem solving and Artificial Intelligence" CEISEE 2014 University of Electronic Science and Technology of China, Chengdu China 24-25 April 2014. 2013
• Turner S (2011) Neural Nets Robotics Workshop. Bot Shop! University of Derby, 28th October 2011.
• Hill G, Turner S (2011) Chapter 7 Problems First Software Industry-Oriented Education Practices and Curriculum Development: Experiences and Lessons edited by Drs. Matthew Hussey, Xiaofei Xu and Bing Wu. ISBN: 978-1609607975 IGI Global June 2011  DOI: 10.4018/978-1-60960-797-5.ch007
• Turner S and Hill G (2010) "Innovative use of Robots and Graphical Programming in Software Education" Computer Education Ser. 117 No. 9 pp 54-57 ISSN: 1672-5913
• Turner S, Hill G, Adams J (2009) "Robots in problem solving in programming" 9th 1-day Teaching of Programming Workshop, University of Bath, 6th April 2009.  
• Turner S and Hill G(2008) "Robots within the Teaching of Problem-Solving" ITALICS vol. 7 No. 1 June 2008 pp 108-119 ISSN 1473-7507 
• Turner S and Adams J (2008) "Robots and Problem Solving" 9th Higher Education Academy-ICS Annual Conference, Liverpool Hope University, 26th August - 28th August 2008. pp. 14 ISBN 978-0-9559676-0-3. 
• Adams, J. and Turner, S., (2008) Problem Solving and Creativity for Undergraduate Computing and Engineering students: the use of robots as a development tool Creating Contemporary Student Learning Environments 2008, Northampton, UK. 
• Adams, J. and Turner, S., (2008) Problem Solving and Creativity for Undergraduate Engineers: process or product? International Conference on Innovation, Good Practice and Research in Engineering Education 2008, Loughborough, UK. 
• Adams, J., Turner, S., Kaczmarczyk, S., Picton, P. and Demian, P.,(2008). Problem Solving and Creativity for Undergraduate Engineers: findings of an action research project involving robots International Conference on Engineering Education ICEE 2008, Budapest, Hungary. 
• Turner S and Hill G(2007) Robots in Problem-Solving and Programming 8th Annual Conference of the Subject Centre for Information and Computer Sciences, University of Southampton, 28th - 30th August 2007, pp 82-85 ISBN 0-978-0-9552005-7-1 
• Turner S (2007) Developing problem-solving teaching material based upon Microsoft Robotics Studio. 8th Annual Conference of the Subject Centre for Information and Computer Sciences, University of Southampton, 28th - 30th August 2007 pp 151 ISBN 0-978-0-9552005-7-1 
• Turner S (2007) Developing problem-solving teaching materials based upon Microsoft Robotics Studio. Innovative Teaching Development Fund Dissemination Day 1st March 2007 Microsoft:London 
• Turner S and Hill G (2006) The Inclusion Of Robots Within The Teaching Of Problemsolving: Preliminary Results Proceedings of 7th Annual Conference of the ICS HE Academy Trinity College, Dublin, 29th - 31st August 2006 Proceedings pg 241-242 ISBN 0-9552005-3-9 

All opinions in this blog are the Author's and should not in any way be seen as reflecting the views of any organisation the Author has any association with.