MOBILE LEARNING AND MATHEMATICS Mobile Learning and Mathematics provides an overview of current research on how mobile devices are supporting mathematics educators in classrooms across the globe. Through nine case studies, chapter authors investigate the use of mobile technologies over a range of grade levels and mathematical topics, while con- necting chapters provide a strong foundational background in mobile learning theories, instructional design, and learner support. For current educators, Mobile Learning and Mathematics provides concrete ideas and strategies for integrating mobile learning into their mathematics instruction—for example, by sharing resources that will help implement Common Core State Standards or by streamlining the process of selecting from the competing and often confusing technology options currently available. A cutting-edge research volume, this collection also provides a springboard for educational researchers to conduct further study. Helen Crompton is Assistant Professor of Instructional Technology in the Department of Teaching and Learning at Old Dominion University in Nor- folk, Virginia, USA. John Traxler is Professor of Mobile Learning at the University of Wolverhamp- ton, UK, where he also directs the Learning Lab. This page intentionally left blank MOBILE LEARNING AND MATHEMATICS Foundations, Design, and Case Studies Edited by Helen Crompton John Traxler First published 2015 by Routledge 711 Third Avenue, New York, NY 10017 and by Routledge 2 Park Square, Milton Park, Abingdon, Oxon OX14 4RN Routledge is an imprint of the Taylor & Francis Group, an informa business © 2015 Taylor & Francis The right of Helen Crompton and John Traxler to be identifi ed as the authors of the editorial material of this work, and of the authors for their individual chapters, has been asserted by them in accordance with sections 77 and 78 of the Copyright, Designs and Patents Act 1988. All rights reserved. No part of this book may be reprinted or reproduced or utilized in any form or by any electronic, mechanical, or other means, now known or hereafter invented, including photocopying and recording, or in any information storage or retrieval system, without permission in writing from the publishers. Trademark notice: Product or corporate names may be trademarks or registered trademarks, and are used only for identifi cation and explanation without intent to infringe. Library of Congress Cataloging-in-Publication Data Mobile learning and mathematics : foundations, design, and case studies / edited by Helen Crompton, John Traxler. pages cm Includes bibliographical references and index. 1. Mathematics—Study and teaching. 2. Mobile communication systems in education. I. Crompton, Helen, editor. II. Traxler, John, editor. QA20.M63M63 2015 510.71—dc23 2014031919 ISBN: 978-0-415-74280-1 (hbk) ISBN: 978-0-415-74281-8 (pbk) ISBN: 978-1-315-81434-6 (ebk) Typeset in Bembo by Apex CoVantage, LLC CONTENTS Introduction 1 Helen Crompton and John Traxler 1 B ridging the Gap: Using Mobile Devices to Connect Mathematics to Out-of-School Contexts 9 S andra F. Sawaya and Ralph T. Putnam 2 M obile Applications for Math Education—How Should They Be Done? 20 M artin Ebner 3 I nquiry-Based Mobilized Math Classroom with Stanford Mobile Inquiry-Based Learning Environment (SMILE) 33 D onggil Song and Paul Kim 4 S martphones Welcome! Preparatory Course in Mathematics Using the Mobile App MassMatics 47 E va Decker, Barbara Meier, Andreas Christ, Gisela Hillenbrand, Stephan Claus, and Robert Koschig 5 S tudents’ Behaviour, Perceptions and Emotions When Learning Mathematics with Cellular Phones 61 W ajeeh Daher and Nimer Baya’a vi Contents 6 D esigning with Mobile Technologies for Enabling Transitions across Mathematical Contexts 71 H åkan Sollervall and Marcelo Milrad 7 B reaking Barriers between Out-of-School and Classroom Mathematics with Documenting 86 T im Jay and Ulises Xolocotzin 8 R ealistic Mathematics Education, Mobile Learning and the Bridge21 Model for 21st-Century Learning: A Perfect Storm 96 B rendan Tangney, Aibhín Bray and Elizabeth Oldham 9 U sing Mobile Games in the Classroom: The Good and the Bad of a New Math Language 106 A nders Kluge and Jan Dolonen 10 G uidelines for Developing Mobile Learning Games for Mathematics Based on a Case Study 122 V ani Kalloo and Permanand Mohan 11 V irtual 10 Frames and Mobile Technology in a Canadian Primary Classroom 135 H elen Wight and Andrew Kitchenham 12 S tudents’ Mathematical Conjectures When Interacting with a Mobile Device 150 S . Aslı Özgün-Koca and Thomas G. Edwards 13 S upport in Hand: Mobile Nudges for Math Success 164 J arek Sierschynski, Colleen Carmean, and Jill Frankfort 14 M obile Help Seeking in Mathematics: An Exploratory Study with Mexican Engineering Students 176 M ario Sánchez Aguilar and Danelly E. Puga 15 C onfessions of a Dr Math Tutor 187 L aurie Butgereit, Adele Botha, and Vicki Boysen 16 C ase Study: Tangerine:Class for Data-Informed Instructional Decision Making in Kenya 198 C armen Strigel, Mildren Lang’o, Dunstone Kwayumba, and Sarah Koko Contents vii 17 M obilizing Mathematics: Participants’ Perspectives on Bring Your Own Device 213 B illie Jean Holubz C onclusion: Mobile Maths: Figuring Out What Comes Next 223 J ohn Traxler and Helen Crompton Contributor Biographies 233 Index 241 This page intentionally left blank INTRODUCTION Helen Crompton and John Traxler The promise and potential of using mobile devices in education is rapidly becom- ing apparent, and there is widespread interest among academic and practitioner communities. Mathematics is one such area where technologically rich milieus are proving advantageous, with empirical evidence indicating that mobile tech- nologies can be used to develop students’ understanding of estimation (Lan, Sung, Tan, Lin, & Chang, 2010), addition, subtraction (Zurita & Nussbaum, 2007), and multiplication (Wei, Hung, Lee, & Chen, 2011). The purpose of this book is to present a collection of theoretical foundations and empirical fi ndings to delineate the affordances of incorporating mobile learning in mathematics. Technology has become affordable and accessible for use in schools, and educa- tors have witnessed the explosive growth of technologies available for the teach- ing and learning of mathematics (Fey et al., 1984). Attributes, such as graphical capabilities quickly identifi ed technologies as positive in facilitating the construc- tion of mathematical understanding (Clements & Battista, 1989, 1994). In other words, from using technology, students are able to cognitively construct networks of relationships linking mathematical concepts and processes. This has caused sig- nifi cant interest among the research community, and researchers have focused on how students are able to extend and enhance mathematical understandings while using these technological environments (Battista, 2007; Lagrange, Artigue, Laborde, & Trouche, 2003). In the last decade, mobile technologies such as smartphones and tablet com- puters have become a new type of computing platform that can be used to push beyond the confi nes of traditional pedagogies. Mobile learning is defi ned as “learning across multiple contexts, through social and content interactions, using personal electronic devices” (Crompton, 2013, p. 4). This method of learning is