ebook img

ERIC EJ1138608: Exploring Common Misconceptions and Errors about Fractions among College Students in Saudi Arabia PDF

2017·1.8 MB·English
by  ERIC
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview ERIC EJ1138608: Exploring Common Misconceptions and Errors about Fractions among College Students in Saudi Arabia

International Education Studies; Vol. 10, No. 4; 2017 ISSN 1913-9020 E-ISSN 1913-9039 Published by Canadian Center of Science and Education Exploring Common Misconceptions and Errors about Fractions among College Students in Saudi Arabia Yazan M. Alghazo1 & Runna Alghazo1 1 Humanities and Social Sciences, Prince Mohammad Bin Fahd University, Alkhobar, Kingdom of Saudi Arabia Correspondence: Yazan M. Alghazo, Humanities and Social Sciences, Prince Mohammad Bin Fahd University, Alkhobar, 31952, Kingdom of Saudi Arabia. Tel: 966-53-004-6438. E-mail: [email protected] Received: November 14, 2016 Accepted: December 15, 2016 Online Published: March 30, 2017 doi:10.5539/ies.v10n4p133 URL: https://doi.org/10.5539/ies.v10n4p133 Abstract The purpose of this study was to investigate what common errors and misconceptions about fractions exist among Saudi Arabian college students. Moreover, the study aimed at investigating the possible explanations for the existence of such misconceptions among students. A researcher developed mathematical test aimed at identifying common errors about fractions as well as short interviews, aimed at understanding the thought process while solving problems on the test, were conducted among a total of 107 (n=107) college students. The findings suggested that the majority of college students in Saudi Arabia hold common misconceptions about fractions and mathematical calculations involving fractions, such as thinking that all fractions are always part of 1 and never greater than 1, and using cross multiplication to solve multiplication problems involving fractions. Keywords: mathematical errors, fractions, common misconceptions 1. Introduction The concept of fractions in mathematics has always been considered a difficult concept to understand by learners. Most learners have hard time thinking about fractions as numbers. They tend to see it only as a calculation on its own (division) or as a complex set of two numbers written on top of each other (Weinberg, 2001). That is why those learners use specific abstract rules to solve problems with fractions without really understanding the interpretations of these rules. The reason why people think rational numbers are difficult to understand is most likely because they can be represented in different ways (parts of a whole, ratios, quotients). Research has shown that the majority of students find fractions to be too difficult and complex when involved in calculations; they find them difficult to visualize and to relate to their daily lives. Mathematical learning is a systematic process that involves building on prior knowledge and mixing different skills and basic concepts in order to achieve mastery of mathematical calculations and procedures (Ashlock, 2001; Sarwadi & Shahrill, 2014). It is, therefore, essential that teachers emphasize the importance of the basic concepts of mathematical understanding at early stages of learning, rather than focusing on memorization of rules and procedures using drill and practice techniques. Students construct their mathematical knowledge and build on previous knowledge they learn; this means that any misconception they develop as they learn mathematics might affect their future learning of similar related mathematical concepts (Vamvakoussy & Vosniadou, 2010), therefore, it is essential that such misconceptions are identified as early as possible in order to guide students in changing those misconceptions and, hence, allow for future understanding of connected more complex concepts. Researchers have investigated mathematical errors and misconceptions and found that students’ mathematical errors lead to future hindering of their academic success in mathematically related topics (Sarwadi & Shahrill, 2014). Vamvakoussi and Vosniadou (2010) conducted a study to investigate students’ understanding of decimals, and concluded that students’ understanding and conceptualization of decimals was robust and that students found it difficult to make the connection between decimals and fractions. Because of the importance of learning fractions, and their use in people’s daily lives (i.e. calculating tips for purchases, discounts, and sharing). The researcher attempts to explore the different misconceptions about fractions among college students. Moreover, this study attempts to shed light on the reasons that lead students to 133 ies.ccsenet.org International Education Studies Vol. 10, No. 4; 2017 develop such misconceptions of fractions. Finally, the researcher proposes activities and methods that can be used to allow students to better understand fractions and to reduce the complexity they face when dealing with calculations involving fractions. 2. Methodology 2.1 Instrument The researcher formulated a set of mathematical problems and questions, in the form a test, relating to fractions. The questions on the test were formulated based on previous literature about common misconceptions among students. The questions were aimed to measure the student’s ability to perform the basic calculations (addition, subtraction, multiplication, and division) with fractions. The questions also aimed at addressing students’ conceptual understanding of fractions (i.e. drawing visual representations of fractions). Also, to shed some light on their understanding of certain rules used in fraction calculations, and their perception of the difficulty of solving problems containing fractions. Some of the questions involved actual calculations, and others were written questions aimed to discover their general understanding of fractions. 2.2 Participants The sample for the study included 107 college level students attending a four year university program in the Kingdom of Saudi Arabia. 77 of the students were male, and 30 were female. All the participants were freshman and sophomore students who have completed all university CORE mathematics courses, which are introduced prior to the students’ entrance to their degree programs, including Introductory Algebra, Intermediate Algebra, Calculus I, and Calculus II. Table 1 shows the distribution of participants in the study per Gender and Year in college. Table. 1. Distribution of participants based on Gender and Year in college Gender/Year Freshman Sophomore Male 46 31 Female 21 9 2.3 Data Collection Data collection took place during regular class hours, where students were asked to volunteer in the study by completing the test and engaging in discussion with the researcher as they submitted their completed tests, the researcher went through the answers with the participants and asked them clarification questions about their methods and thinking process they utilized to solve the problems. Data were collected during Spring-2016 semester, and it took approximately two weeks to collect all data from participants. The purpose of the short interview was to shed more understanding on the students’ thought process as they completed the items on the test. According to Vamvakoussi and Vosniadou (2010), interviewing students allows researchers to better understand the process of thinking involved in solving mathematical problems and, consequently, better identifying what misconceptions students hold, which lead to mathematical errors in solving problems. 3. Results and Discussion Data analysis after grading the test revealed some common misconceptions among majority of students. Table 2 shows those common misconceptions and errors as well as their percentages among the participants. In the following sections, all of those common errors are discussed, as well as other common themes that emerged through the data analysis process. Table 2. Common errors and misconceptions among college students Error/Misconception No. of students Percentage All fractions are always part of 1, never bigger than 1 88 83% Multiplication makes numbers bigger, and division makes them smaller 92 87% Using cross multiplication to solve fraction multiplication problems 60 57% The larger the denominator the smaller the fraction regardless of nominator 103 98% “All fractions are always part of 1, never bigger than 1” (Mcleod & Barbara, 2006). 134 ies.ccsenet.org Internationnal Education Stuudies Vol. 10, No. 4;2017 Most learnners and studennts have this mmisconception,, and the reasoon is because sstudents do nott view a fractioon as a single nuumber. They seee fractions as either two nummbers dividedd by each otherr, or a complexx number writtten in a strange fformat that theey are too diffficult to concepptualize. Whenn asked about this misconceeption, the majjority of the studdents answeredd that it is truee, and only 18 of them realizzed that it is nnot true that evvery fraction iss less than 1. When a sttudent sees a ffraction that is greater than oone, he or she does not thinnk of it as a fraaction but simply a division caalculation. Thee students that answered truee to the questioon about whatt they think aboout the fraction 6/3 = 2, and hhow this fractiion proves thee statement of all fractions bbeing smaller than one wronng, their respoonses showed that they did nott have a clear uunderstandingof proper andimproper fracctions. Multiplicaation makes nnumbers biggeer, and divisioon makes themm smaller: 87% of thee participants aalso agreed wiith this statemeent; once the reesearcher askeed them to expplain how 6 x ½½ = 3 fits with ttheir assumptiion, they explained that thhey do not innclude fractionns with generaal questions aabout mathematiical operationss. One of the student said “I only think of whole nummbers, NOT ffractions.” Another student saiid that this is aa rule he learnned in school, aand he did nott pay attentionn to whether it can be generaalized to fractionns or not becauuse “fractions aare different.” This obvioously indicatess that students do not undersstand that fracttions are part oof the real nummbers. They do not see fractioons as single nuumbers on thee number line;they have an assumption thhat they are diffferent with sppecial difficult ruules. To check iif students see fractions as nnumbers on thee number line (See Figure 1for a number line that includes a fraction). SStudents were asked how mmany fractions there are betwween ½ and ¼¼. Only twelve students answwered infinity, wwhich is the coorrect answer, and the rest ggave answers tthat varied from one to 10. That reveals eeither students’ lack of understtanding of the number line iitself or that sttudents see fraactions as a divvision problemm or a number tooo complicatedd to even be iincluded in thhe number linee, or along wwith other simppler numbers. This agrees witth the findingss of Vamvakouussi and Vosniiadou (2010), who found that the majorityy of participannts in their studyy were not able to determinne how many decimals exisst between 0.55 and 0.6. Simmilarly, Durkinn and Rittle-Johnnson (2015) coonducted a stuudy on studentt misconceptioons and found that the majorrity of studentts are not able too place a numbber on the nummber line. Figgure 1. Number line that showws fractions Adding annd subtracting Fractions: Most studeents find addittion and subtraaction of fractiions tricky beccause of havingg to find a commmon denominnator. However, 96% of the pparticipants annswered the adddition probleem correctly. TThey were abble to explain their answer annd demonstrate how they ccalculated the common dennominator firstt and then caalculate the simple addition or subtraction. Some of the rremaining studdents knew thhe answer for ½ + ¼ = .75 bbut were unabble to represent tthat number inn fractions, andd wrote it as 7/5. Also, studdents who couuld answer the question coulld also providde explanatoryy drawings of their answers (See Figure 2 ffor examples oof students draawing represenntations of fraaction additionn). However, tthey used thesame “rule” whhen asked to ssolve problemms that containned fraction ddivision and mmultiplication; which meanss that students mmemorize the “rules” they aare taught aboout doing fracttion calculatioons and somettimes they connfuse those ruless and over timee this confusioon ends up beinng a misconcepption about theeir basic skillss with fractionss. 135 ies.ccsenet.org Internationnal Education Stuudies Vol. 10, No. 4;2017 Figurre 2(a). Drawinng representatiions of ½ + ¼ Figuree 2(b). Drawinng representations of ¼ +1 ¼¼ Multiplicaation and diviision of fractioons: One of thhe students intterviewed saidd: “Fractions aren’t hard foor me to do bbut I sometimmes have probblems multiplyinng them.” Manny of the studennts intervieweed also agreedthat division aand multiplicattion are the haardest operation to deal with in problems innvolving fractiions. Division of fractions hhas been descrribed as one oof the most compplicated and leeast understoood content dommains (Aksu, 11997; Tirosh, 2000). It appeears that the reeason for this is that most studdents memorizze the calculatiions performedd on fractions as an abstractt set of rules. TThus, since divission is the rulee with the most number of “steps” wheree you need to ffind the reciprrocal of the seecond fraction annd then multiplly it by the firsst fraction; stuudents find it thhe hardest to mmemorize and wwith time theyy tend to forget oor get confusedd about which rrule to use witth which of thee four basic opperations. Researchers believe thaat another reason why divvision is diffficult for studdents is that students can only conceptuallize dividing aa larger numbeer by a smalleer number (Saddi, 2007). Onlyy 43% of the participants soolved 136 ies.ccsenet.org Internationnal Education Stuudies Vol. 10, No. 4;2017 the problemm 3/5 ÷ 2/3 coorrectly, and onnly 33% of thoose students could draw a reeasonable pictoorial representtation of the equuation. (See Figgure 3 for picttorial represenntation on fracttion division). This also indiicates that even the students thhat solved the pproblem correectly did not unnderstand exacctly how they ssolved it. Theyy only remembbered the rules aand explained iit by saying “thhat’s how I waas taught to doit.” Figure 3. Different pictoorial representtations of 3/5 ÷÷ 2/3 Another pproblem studennts solved incorrectly was tthe problem aabout multipliccation. When asked to solve the problem 2//5 x 3/4, the mmajority of the students cross-multiplied annd their answerr was 8/15 for this problem. AAfter the researccher explainedd the correct aanswer to themm, which woulld be 6/20, moost of them arrgued that theyy are used to utiilizing calculattors to solve suuch problems.They also saidd they were faamiliar with thaat rule but theyy just forgot it beecause they rarrely used it. Weak connceptual understanding of tthe meaning oof fraction: Another quuestion on thee test was to arrrange a numbber of fractions in the order from the smalllest to the bigggest. The fractioons were 4/5, 1/3, 5/4, 4/9, 11/2. Only 2% aanswered correectly (1/3, 4/9, 1/2, 4/5, 5/4)), while 98% oof the students gave very interresting answerrs that revealedd misconceptioons about studdents understannding of the aactual representaation of the ffrraction (the nnominators annd the denomiinator). This finding suppoorts other reseearch findings reegarding compparing and orddering fractionns, where studdents were fouund to have diifficulty comparing fractions ccorrectly (Durkkin & Rittle-Joohnson, 2015). The studennts seemed to think that thee larger the deenominator is tthe smaller the fraction is, nno matter whaat the nominatorr is (see Figuree 4 for example of students’ answers to arrranging fractioons). The majoority of the studdents who answwered this quesstion wrong haad one of two explanations for their mistaakes: one was that they beliieved that the deenominator exppressed “how many pieces tthere are” so tthe larger it is the smallest thhe number will be; One of thee students expplained this as a pizza slice representationn. For examplee a pizza sliceed into 9 piecees, so each piecee is smaller thaan they wouldd be if the samme pizza was slliced into 5 piieces. What thee students failed to see here iss that a fractioon not only reppresents the siize of those sllices of pizza, but also howw many of themm are available. The seconnd explanation was that they simply did noot understand tthis representattion of x/y as quantity. Theyy said that wheneever they needded to solve suuch problems they would usse the calculattor to find out the answer, wwhich the researccher found verry interesting, because one oof the studentss who actuallyy found the coorrect answer ccould not solve tthe problem wiithout first connverting each oone of the fractions into a peercentage. 137 ies.ccsenet.org Internationnal Education Stuudies Vol. 10, No. 4;2017 Another innteresting findding among alll participants is that all of them with noo exceptions toook a considerable amount off time solving the problems iin the questionnnaire. The reaason for that laack of problemm solving skillwith fractions is contributed tto using calculators becausee 90% of the sttudents, at onee point, asked if they could uuse a calculator. They expresssed they weree uncomfortabble trying to ffiind the answeers by paper ppencil calculattions. When the researcher assked some of them why thhey needed a ccalculator, theeir response wwas “It’s a fraction problem.” Figure 4. Examples of sstudent’s soluttions to the queestion: Arrangee these numbeers from smalleest to biggest. AAnd explain why?? 4/5, 1/3, 5/4,4/9, 1/2 One of thee student’s inteerviewed reveaaled more prooof of some studdents’ lack of understandingg of nominators and denominattors. The reseaarcher asked hiim to represennt the fraction 22/5 for verballly and by drawwing if possiblee. He said that thhe fraction 2/5 means: “two ppeople sharingg five apples”,which clearlyy indicates he ddoes not understand the relationnship betweenn the nominatoor and denominnator. Which is the basis forr understandingg what a fractiion is and what iit represents (see Figure 5 for false representation of 2/5))? Figuure 5. False reppresentations oof fraction 2/5 In order too understand wwhy students ddevelop misconnceptions in frraction calculaations, we needd to investigatte the 138 ies.ccsenet.org International Education Studies Vol. 10, No. 4; 2017 reasons that students find fractions to be complicated and hard to understand. One of the most common reasons for this lack of ability to understand fractions is that students do not see fractions as real numbers. Hence, they find it difficult to solve problems that include more than one fraction because, for example, dividing a fraction by a fraction means that there are three division operations in the same problem. Which, eventually, makes them grow to dislike solving and dealing with such problems. Ahmed, one of the students interviewed said, “Fractions are just an annoyance. There is complications that every student finds when trying to solve them. Memory on how to solve them becomes repressed as one resents them more and more. I forgot how to divide them. Even as a math major, I wish they weren’t so common in math courses.” Because students find fractions complicated, they spend more time trying to memorize the rules for calculations rather than spending time trying to understand them. This leaves those students with a very thin layer of knowledge regarding fraction calculations. And any memory loss of one of the rules will result in a misconception about that rule that might stay uncorrected for a long time, and even through their college years. Allowing the use of calculators in schools has also added to this problem because students didn’t need to work harder on fractions they could not understand. All they had to do is just punch in the numbers into the calculator; gradually this made students more dependent on calculators. And less eager to actually learn how to do the calculations as long as they can get the final answer, even if sometimes it doesn’t make sense. This means that children’s conceptual understanding of fractions will be reduced and hence, they will not be able to reach mathematical proficiency with fractions. 4. Conclusion The purpose of this study was to explore the common mathematical misconceptions among college students about fractions. Since research shows that many of the problems students have with fractions are caused by their lack of understanding of fraction as real numbers, we need to find ways to help introduce fractions to students in a more simple and comprehendible manner. One approach for this is to start introducing fractions as pictorial and visual images long before the actual symbolic fraction format is introduced. This will help students gain a deeper understanding of the “part of whole” concept of fractions. Another way to help students conceptualize fractions and the four operations is using word problems that would help support their conceptual understanding of fractions. These word problems should connect their daily life activities with concepts they would encounter when learning about fractions. Such questions also would help students understand that division doesn’t always have to make numbers smaller because they will be able to read division problems relating to their daily lives that do not reduce numbers. Sharp suggested posing word problems as a means to help student gain better understanding of fractions (2002): Here I have 2 ¼ cups of orange juice. I take medicine each day and my doctor wants me to limit the amount of orange juice I drink when I take my medicine. I can have ¾ cups of orange juice each day with my breakfast. For how many days can I have orange juice? (Whole number answer) Although most students in this study chose to represent their fractions with money or pizza’s and thought it to be the easiest for most other students to understand. We should also consider the cultural differences and varieties. People have different cultures and different lifestyles. This means that while money might be an easy concept for middle-class children to relate to, it might be considered to be very hard by children of poor communities. Racial, gender, and socio-economic status of children need be considered when teachers try to convey fractions to students using word problems or pictorial representations (Sleeter, 2005). They need to try to address most of the children’s backgrounds within their examples. Another issue is that students should not be allowed to use calculators at early grades to calculate fractions. This will help students learn to rely more on paper and pencil calculations, which will allow a more persistent and deeper understanding and memorizing of calculation methods with fractions. When students use calculators their sense of number is reduced. They give complete trust to the calculator and they end up being convinced by false answers, generated by mistaken finger hits perhaps, yet the students will lose the ability to use any reasoning in examining their answers. For example: if a student tries to calculate 15/5 and he accidentally hits 5/5 and gets one for an answer, he wouldn’t use reasoning to see that his answer isn’t correct and that 15/5 cannot be equal to one. He would just give one as an answer. Furthermore, it is essential for teachers to understand that students bring a form of informal knowledge, which they acquire from their outside lives, into school (National Research Council, 2001). Teachers need to be able to evaluate the amount of the information each student has and the correctness of this information. This knowledge 139 ies.ccsenet.org International Education Studies Vol. 10, No. 4; 2017 should be nurtured and attended to by teachers because it could be the basis for a well-founded understanding of fractions. An example of this informal knowledge can be the notion of sharing. Children learn to share at a very young age, and this concept ideally is the basis for understanding fractions. References Aksu, M. (1997). Student performance in dealing with fractions. The Journal of Educational Research, 90(6), 375-380. https://doi.org/10.1080/00220671.1997.10544595 Ashlock, R. B. (2001). Error patterns in computation: Using error patterns to improve instruction. Prentice Hall. Durkin, K., & Rittle-Johnson, B. (2015). Diagnosing misconceptions: Revealing changing decimal fraction knowledge. Learning and Instruction, 37, 21-29. https://doi.org/10.1016/j.learninstruc.2014.08.003 Flores, J., & Franklin, M., Huynh, T., & Sprague, J. (2008). Fraction in Elementary Grades. EeeWiki. Retrieved December 5, 2009, from http://eee.uci.edu/wiki/index.php/Fraction Mcleod, R., & Newmarch, B. (2006). Maths4life fractions Booklet. National Research and Development Centre for Adult literacy and numeracy. Retrieved Dec, 5, 2009, from http://www.nrdc.org.uk/publications_details.asp?ID=69 National Research Council. (2001). Adding it up: Helping children learn mathematics. In J. Kilpatrick, J. Swafford, & B. Findell (Eds.), Mathematics Learning Study Committee, Center for Education, Division of Behavioral and Social Sciences and Education. Washington, DC: National Academy Press. Sadi, A. (2007). Misconceptions in numbers. UGRU Journal, 5, 1-7. Sarwadi, H. R. H., & Shahrill, M. (2014). Understanding students’ mathematical errors and misconceptions: The case of year 11 repeating students. Mathematics Education Trends and Research, 2014, 1-10. https://doi.org/10.5899/2014/metr-00051 Sharp, J., & Adams, B. (2002). Children’s constructions of knowledge for fraction division after solving realistic problems. Journal of Educational Research, 95(6), 333-347. https://doi.org/10.1080/00220670209596608 Tirosh, D. (2000). Enhancing prospective teachers’ knowledge of children’s conceptions: The case of division of fractions. Journal for Research in Mathematics Education, 5-25. https://doi.org/10.2307/749817 Vamvakoussi, X., & Vosniadou, S. (2010). How many decimals are there between two fractions? Aspects of secondary school students’ understanding of rational numbers and their notation. Cognition and instruction, 28(2), 181-209. https://doi.org/10.1080/07370001003676603 Weinberg, S. L. (2001, April). Is there a connection between fractions and division? Students’ inconsistent responses. Paper presented at the Annual Meeting of the American Educational Research Association, Seattle, WA. Copyrights Copyright for this article is retained by the author(s), with first publication rights granted to the journal. This is an open-access article distributed under the terms and conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by/4.0/). 140

See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.