Investigating key functions of hand movements by individuals with visual impairment: Improving teaching practices in special education through research
Article Sidebar
Main Article Content
Abstract
Abstract
Research is still ongoing with regard to types of exploratory movement by active touch and its key functions in individuals with visual impairment. The aim of the present study was to describe and identify different types of exploratory movement performed by individuals with visual impairment in their exploration of geometric shapes. A total of twelve participants were asked to explore a number of simple and complex geometric shapes. The research design consisted of two research phases. In the first phase, the participants were asked to describe and, if possible, to identify the properties of each shape. In the second phase, the participants were asked to describe their hand movements during active exploration. The findings indicated that the participants utilized different movements to extract the featural and global properties of the shapes. It was also observed that some patterns of exploratory movement were present in all of the participants’ strategies, which indicated issues of laterality. Finally, the research highlighted that by observing patterns of exploratory movement, educators of students with visual impairment can determine which strategies may be worth exploring with a view to their adoption in teaching practices and instruction.
Â
Keywords: visual impairment, active touch, geometric shapes, think -aloud protocols, laterality, teaching practices
Downloads
Article Details
Authors who publish with this journal agree to the following terms:
- Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
- Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
- Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See The Effect of Open Access).
References
C.L. Philip Chen, C.-Y. Zhang, Data-intensive applications, challenges, techniques and technologies: A survey on Big Data, Inf. Sci. (Ny). 275 (2014) 314–347. doi:10.1016/j.ins.2014.01.015.
M. Chen, S. Mao, Y. Liu, Big data: A survey, Mob. Networks Appl. 19 (2014) 171–209. doi:10.1007/s11036-013-0489-0.
S. Yin, O. Kaynak, Big Data for Modern Industry : Challenges and Trends, Proc. IEEE. 103 (2015) 143–146. doi:10.1109/JPROC.2015.2388958.
Wired.com, Google Is 2 Billion Lines of Code—And It’s All in One Place, (2015). http://www.wired.com/2015/09/google-2-billion-lines-codeand-one-place/ (accessed December 12, 2015).
M. Salmanoğlu, K. Öztürk, S. Bağrıyanık, E. Ungan, Benefits and Challenges of Measuring Software Size : Early Results in a Large Organization, in: IWSM Mensura, 2015.
R. Robbes, R. Vidal, M.C. Bastarrica, Are Software Analytics Efforts Worthwhile for Small Companies ? The Case of Amisoft, IEEE Softw. SEPTEMBER/ (2013) 46–53.
B. Kitchenham, S. Charters, Guidelines for performing Systematic Literature Reviews in Software Engineering, Tech. Rep. (2007).
M. Khabsa, C.L. Giles, The Number of Scholarly Documents on the Public Web, (2014). doi:10.1371/journal.pone.0093949.
Aa. Tay, 8 surprising things I learnt about Google Scholar, (2014). http://musingsaboutlibrarianship.blogspot.com.tr/2014/06/8-surprising-things-i-learnt-about.html#.VoeMGvmqqN3 (accessed November 30, 2015).
R. Malhotra, A. Jain, Fault Prediction Using Statistical and Machine Learning Methods for Improving Software Quality, J. Inf. Process. Syst. 8 (2012) 241–262.
D.H. (Polo) Chau, Data Mining Meets HCI: Making Sense of Large Graphs, Carnegie Mellon University, 2012.
A. Telea, L. Voinea, Visual software analytics for the build optimization of large-scale software systems, Comput. Stat. 26 (2011) 635–654. doi:10.1007/s00180-011-0248-2.
R.P.L. Buse, T. Zimmermann, Information Needs for Software Development Analytics, in: 34th Int. Conf. Softw. Eng., 2012: pp. 987–996.
A. González-torres, F.J. GarcÃa-peñalvo, R. Therón-sánchez, R. Colomo-palacios, Science of Computer Programming Knowledge discovery in software teams by means of evolutionary visual software analytics, Sci. Comput. Program. 1 (2015) 1–20. doi:10.1016/j.scico.2015.09.005.
J. Kätevä, P. Laurinen, T. Rautio, J. Suutala, L. Tuovinen, DBSA - A Device-Based Software Architecture for Data Mining, in: 2010 ACM Symp. Appl. Comput., 2010: pp. 2273–2280.
M. Wermelinger, Y. Yu, Some Issues in the “ Archaeology †of Software Evolution, Gener. Transform. Tech. Softw. Eng. (2011) 426–445.
F. Fotrousi, Analytics-based Software Product Planning, Blekinge Institute of Technology, 2013.
A. Begel, T. Zimmermann, Analyze this! 145 questions for data scientists in software engineering, Proc. 36th Int. Conf. Softw. Eng. - ICSE 2014. (2014) 12–23. doi:10.1145/2568225.2568233.
K.M. Anderson, Embrace the Challenges : Software Engineering in a Big Data World, in: First Int. Work. BIG Data Softw. Eng., IEEE Press, 2015: pp. 19–25. doi:10.1109/BIGDSE.2015.12.
X. Fern, C. Komireddy, V. Grigoreanu, Mining Problem-Solving Strategies from HCI Data, ACM Trans. Comput. -Human Interact. 17 (2010). doi:10.1145/1721831.1721834.
E.A. El-sebakhy, Expert Systems with Applications Functional networks as a novel data mining paradigm in forecasting software development efforts, Expert Syst. Appl. 38 (2011) 2187–2194. doi:10.1016/j.eswa.2010.08.005.
R. Hewett, Mining software defect data to support software testing, Appl. Intell. 34 (2011) 245–257. doi:10.1007/s10489-009-0193-8.
H. Tribus, I. Morrigl, S. Axelsson, Using Data Mining for Static Code Analysis of C, Adv. Data Min. Appl. (2012) 603–614.
M. Bruntink, Science of Computer Programming Towards base rates in software analytics Early results and challenges from studying Ohloh, Sci. Comput. Program. 97 (2015) 135–142. doi:10.1016/j.scico.2013.11.023.
C. Gupta, K. Viswanathan, L. Choudur, R. Vennelakanti, P. Helm, A. Dev, et al., Better Drilling Through Sensor Analytics : A Case Study in Live Operational Intelligence, in: Fifth Int. Work. Knowl. Discov. from Sens. Data, ACM, 2011: pp. 8–15.
R. Souza, C. Chavez, R.A. Bittencourt, Rapid Releases and Patch Backouts : A Software Analytics Approach Code Integration at Mozilla about Rapid Releases at Mozilla, IEEE Softw. 32 (2015) 89–96.
T. Cerqueus, E.C. De Almeida, S. Scherzinger, Safely Managing Data Variety in Big Data Software Development, in: BIGDSE 2015, IEEE/ACM, 2015. doi:10.1109/BIGDSE.2015.9.
R. Heimgärtner, H. Kindermann, Revealing Cultural Influences in Human Computer Interaction by Analyzing Big Data in Interactions, Act. Media Technol. (2012) 572–583.
F.A. Batarseh, A.J. Gonzalez, Predicting failures in agile software development through data analytics, Softw. Qual. J. (2015). doi:10.1007/s11219-015-9285-3.
M. Beller, G. Gousios, A. Zaidman, How (Much) Do Developers Test?, in: 2015 IEEE/ACM 37th IEEE Int. Conf. Softw. Eng., 2015: pp. 559–562. doi:10.1109/ICSE.2015.193.
S. Banerjee, B. Cukic, On the cost of mining very large open source repositories, in: First Int. Work. BIG Data Softw. Eng., IEEE Press, 2015: pp. 37–43. doi:10.1109/BIGDSE.2015.16.
W.D. Sunindyo, T. Moser, T. Wien, D. Dhungana, Improving Open Source Software Process Quality Based on Defect Data Mining, in: SWQD, 2012: pp. 84–102. doi:10.1007/978-3-642-27213-4.
M. Gayathri, A. Sudha, Software Defect Prediction System using Multilayer Perceptron Neural Network with Data Mining, Int. J. Recent Technol. Eng. 3 (2014) 54–59.
A. Gonzalez-Torrez, R. Theron, F.J. Garcia-Penalvo, M. Wermellinger, Y. Yu, Maleku : an evolutionary visual software analytics tool for providing insights into software evolution Conference Item Maleku : an evolutionary visual software analytics tool for providing insights into software evolution, in: Softw. Maint. (ICSM), 2011 27th IEEE Int. Conf., IEEE, 2011.
C. Rosen, B. Grawi, E. Shibab, Commit Guru : Analytics and Risk Prediction of Software Commits, in: 10th Jt. Meet. Found. Softw. Eng., ACM, 2015: pp. 966–969.
C. Li, L. Huang, L. Chen, Breeze graph grammar : a graph grammar approach for modeling the software architecture of big data-oriented software systems, Softw. Pract. Exp. (2015) 1023–1050. doi:10.1002/spe.
R. Liu, Q. Li, L. Mei, J. Lee, Big Data Architecture for IT Incident Management, in: 2014 IEEE Int. Conf. Serv. Oper. Logist. Informatics (SOLI), IEEE, 2014: pp. 424–429.
A. Bovenzi, F. Brancati, S. Russo, A. Bondavalli, A Statistical Anomaly-Based Algorithm for On-line Fault Detection in Complex Software Critical Systems, Comput. Safety, Reliab. Secur. (2011) 128–142.
A.T. Misirli, B. Caglayan, A. Bener, B. Turhan, A Retrospective Study of Software Analytics Projects : In-Depth Interviews with Practitioners, IEEE Softw. 30 (2013) 54–61.
C. Lopez-martin, A. Chavoya, M.E. Meda-campaña, A Machine Learning Technique for Predicting the Productivity of Practitioners From Individually Developed 6 Software Projects, in: 2014 15th IEEE/ACIS Int. Conf. Softw. Eng. Artif. Intell. Netw. Parallel/Distributed Comput., IEEE, 2014: pp. 1–6.
H. Chen, R. Kazman, S. Haziyev, O. Hrytsay, Big Data System Development : An Embedded Case Study with a Global Outsourcing Firm, in: First Int. Work. BIG Data Softw. Eng., IEEE Press, 2015: pp. 44–50. doi:10.1109/BIGDSE.2015.15.