It Takes Creativity To Be Smart

The ultimate goal of education is to be able to solve problems in the real world. For many young children this has meant entering the empirical world of hard core academic training at a very young age. Parents who fear their children will not be able to compete unless they learn reading and arithmetic early in life, are pushing their children into academics when they are very young. These parents believe that their children will fall behind in elementary school if they are not exposed to "drill and test" programs in their preschools.

The problem with this line of thought is that it is just plain wrong. Children who are forced to memorize rather than rationalize will be able to play back the information they received but will not be able to do anything creative with that information. Very young children are naturally curious and open to exploring the possibilities around them. If we fill them up with facts instead of encouraging creative exploration they will lose the ability to be creative with the facts we have given them. In other words it takes creativity to perform any kind of problem solving whether it is a math problem or a science problem.

Yet when we look at the preschool and elementary school world today we find fewer outlets for creativity and more "teach to test". We find less recess time, no art class, no music and no drama. For all the emphasis on teaching "the basics", I believe that academics are important, but studies show that this early emphasis on only hard core academics can result in poor academic performance when these children reach middle and high school. There are no studies that validate this push for early academics while there are studies that show the opposite.

If you want your child to be smart, you need your child to be creative. At these very young ages what your child needs is brain development activities not memorization. Young children need to learn how to recognize symbols and what those symbols stand for, to recognize the shapes of letters and numbers. Most importantly they need to understand that those letters and numbers are just symbols not reality. If they understand this their brains will be more open to thinking in abstract as well as factual reality.

As I said before it takes creativity to solve problems. It takes creativity to be comfortable facing a new problem and knowing how to approach solving it. If I know that 2 plus 2 =4 but I don't know how to imagine having 2 sticks and then picking up 2 more so I have 4 sticks, then it will be difficult for me to solve a "story problem" in my algebra class. The child needs to know the world is not black and white though the colors black and white do exist in the world. The child needs to know it is OK to take a risk and go outside the box intellectually, to solve a math problem by drawing on something learned while drawing or playing music. A creative child will sense the 'math' in art and music.

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Teacher knowledge: A crucial factor in supporting mathematical learning through play

This paper reports on the mathematical thinking taking place during play in a sessional kindergarten.  It identifies ways in which early childhood teachers can broaden their professional development in mathematics education, and indeed why many early childhood teachers might need to do so, in order to enhance the mathematical learning of their children.  Narratives in the form of learning stories, and photographs of the children at play, augmented and supported the findings of the investigation.

Introduction
There has always been an assumption that in the early years the initial stages of a child's mathematics learning can be seen through their play.  While the child learns by doing, however, the teacher teaches by knowing.  Therefore in order to maximise support of this early mathematical learning an early childhood teacher needs a thorough and extensive mathematical knowledge-base, coupled with theory and experience of appropriate professional pedagogy.  Too often the teacher is bereft of sufficient mathematical knowledge with which to fully employ appropriate skills and strategies needed to enhance mathematical knowledge for the child.

The significance of play in developing early mathematics understanding

Play creates a natural environment of discovery for children, allowing them to learn about themselves and the world around them.  According to Stone (1995) play is defined as an intrinsically motivated, freely chosen, process-oriented over product-oriented, non-literal, and enjoyable activity.  Play serves an important function in children’s holistic development, which includes physical, emotional, social and intellectual growth.  Through play children learn to think for themselves, to make choices and decisions, to reflect, and to tolerate uncertainty, thus enabling them to become more flexible and confident in themselves.  These are important and integral aspects of both the early childhood curriculum, Te Whaariki (Ministry of Education, 1996) and the national mathematics curriculum, Mathematics in the New Zealand curriculum (Ministry of Education, 1992).

Pound (1999) believes the thinking in action which occurs in play forms a rich foundation for the more subject-specific problem solving, mental imaging and recording, in mathematics education, that can develop from play.  Much of what young children learn is incidental, or natural, and happens through their play.  They also observe adults using mathematics for meaningful purposes, and begin to use number and other mathematical concepts themselves as part of their everyday lives.

Young children as problem solvers

Mathematical know-how is the ability to solve problems which require some degree of independence, judgement, originality and creativity, as well as the ability to solve routine problems (Polya, 1995 cited in Pound, 1999).  Mathematics, like all other human knowledge, is a consequence of social interaction.  It is a means, or framework, used to support ongoing enquiry into aspects of the world (Pateman & Johnson, 1990 cited in Steffe & Wood, 1990).

How children go about learning mathematics varies greatly from child to child according to cultural background, family orientation to mathematics, the child’s own disposition to learning, and teacher confidence.  Carr (1999) writes of children’s emerging working theories about what it is to be a learner, and about themselves as learners.  She had earlier developed the idea that the working theories were made up of packages of learning dispositions and defined such dispositions as "habits of mind", or "patterns of learning".  She further developed a framework of learning dispositions (Carr, 1998), known as learning stories, closely linked to the strands of Te Whaariki  (Ministry of Education 1996).  The framework of dispositions included courage and curiosity, trust, perseverance, confidence to express an idea, and taking responsibility for fairness and justice.  In particular, these dispositions support quality mathematics learning through children’s engagement in the problem solving nature of the mathematical processes (Ministry of Education, 1992).

Teachers supporting early mathematics learning

Early childhood teachers have a vital role in the total educative process. Alexander (1997, cited in Pound, 1999: 35), believes teachers have a responsibility to make sure that the "imperatives of early childhood" are not lost among the noisy demands for early achievement.  Meade (1997) found, when referring to learning related to early literacy, early mathematics and reasoning, that most early childhood teachers opted for children to learn about these through play with little adult intervention.  Children, however, do not learn mathematics unless exposed to it, and thus it requires a teacher to have a commitment to both the pedagogical principles of early childhood and personal mathematical knowledge in order to provide mathematically rich environments which do not interfere with the child-centred nature of play.  As Haynes (2000: 101) says

It is personal knowledge and disposition which enables teachers to take a "national curriculum and turn it into a child’s curriculum". (citing Malaty, 1996).

The level of mathematical knowledge held by teachers might well vary, but, without the confidence and skill to interpret children’s activities in learning situations, the actual teaching will be less effective than it could be.  This comes down to how well the teachers themselves have been educated, which in turn depends upon the quality and focus of teacher education to which, as students, they were exposed.  Farquhar (1994) believes that improvement in the quality of early childhood education programmes can best come from the improved quality of teachers, a corollary of which is that only the best applicants should be recruited to teach young children.  Addressing a Teacher Refresher Course for early childhood teachers, Aitken (2000) pointed out that teachers all need highly developed skills, not just amateur understandings, if they are to analyse and respond effectively to each individual child or student’s learning capability and progress.  The importance of quality teacher education cannot be overlooked if teachers are to provide quality learning (Snook, 1992, cited in Farquhar, 1994).  Further to this, Evans and Robinson (1992, cited in Farquhar, 1994), asserted that early childhood teachers should be versatile, flexible and creative in order to effectively manage the multiplicity of their roles and relationships.  This would appear to be no less true in regard to mathematics learning than to other disciplines.

Teachers need to have the subject knowledge and teaching strategies which allow them to extend children’s foundational knowledge (Cullen, 1999).  Further, says Cullen, it is important for teachers to have confidence in their own knowledge of mathematics and to value the conceptual thinking that emerges through play, to recognise its potential for higher level thinking, and to take action accordingly.  Haynes (1999) states that theories about facilitating play are not sufficient: teachers need sound knowledge of mathematical concepts themselves in order to address the 'what' of mathematics teaching.  These observations complement the assertions of Farquhar (1994) and Pound (1999) that educating the educators is of paramount importance for optimal teaching outcomes at whatever level.  As well as teaching for learning, providers of teacher-education must be able to enthuse their students, to know their subjects, to have a sense of humour, and to have a high sense of self-esteem, according to McInerney & McInerney (1998).  Early childhood teachers, themselves, need a positive disposition towards mathematics in order to encourage children to think and reflect.  They need to be able to use their own ideas as a basis for getting children to think and reflect, and to create situations in which the children can gain an awareness of specific content.  Cullen (1999) believes strongly that young children need teachers who are immersed in subject-knowledge but are also able to impart their knowledge by developing reflective, analytical, creative and practical thinking about that knowledge-base.  This validates the appropriateness of Mathematics in the New Zealand curriculum (Ministry of Education, 1992), (MiNZC), as a framework for the development of mathematical concepts in early childhood through its emphasis on process as an integral part of mathematical learning.

Gathering the data

The study was conducted in the researcher’s own place of practice, a kindergarten, with 44 four-year-old children in morning session as subjects.  The kindergarten concerned is located in a middle-class socio-economic area in which all local schools are decile 10.  The children came from a variety of cultural backgrounds, although mainly from New Zealand Pakeha and Asian cultures.

The study began with observations, both written and photographs, of children at play in a variety of situations within the kindergarten.  The written observations were recorded as narratives in the form of learning stories (Carr, 1998).  Initially the aim was to look at five areas of play to see what was happening in each, and later to analyse the learning story to identify any mathematical thinking taking place.  This was to be further analysed and categorised according to criteria drawn from MiNZC (Ministry of Education 1992).  In the event, eighteen learning stories in nine areas of mathematics were completed, and each was then categorised against one of the five content strands of MiNZC (number, measurement, geometry, algebra, statistics).  In light of this, and the initial focus on a small number of areas of play, the investigation was extended further into most recognised areas of play in a kindergarten.  Another thirteen observations were made in these areas and analysed using the same criteria.

The researcher herself had trained as a kindergarten teacher thirty years previously, which was well before the implementation of both the national curriculum for early childhood education and the national mathematics curriculum.  While having worked with Te Whaariki (Ministry of Education 1996), she was actually unaware of the contents and components of MiNZC prior to undertaking the study

Summary of results

Every learning story identified some mathematical activity, thinking, and/or mathematical language within the play concerned. The seventeen areas of play observed were sand, science, puzzles, games, mat-time, outdoor adventure, see-saw, woodwork, family, dough, cooking, collage, music, water, blocks, pen and paper and hide and seek.  Table 1 indicates the instances of mathematical thinking observed across these areas of play grouped according to the content strands of MiNZC.

  

Table 1. Play observations and strands of MiNZC

All thirty one observations related to a specific MiNZC strand, and all but six indicated mathematical activity across a second strand as well, evidenced in the same observation.  This confirmed that concepts of level one mathematics are emerging through play before school.

Mathematical thinking associated with the number and measurement strands were predominant and the strands of mathematics do not occur in isolation is illustrated by the number of observations where instances of two strands were demonstrated.

A significant feature of this research was the analysis of the photographic records for mathematical content.  The various facial expressions of the children gave some indication of how the experience affected them during play, illustrating a variety of dispositions such as enthusiasm, curiosity and concentration.  Together with the written observations, they are indicative of the children's positive attitudes to mathematical exploration.  At this age most children are curious and experiment readily, but it has been demonstrated here that the actual breadth of mathematical learning depends upon the levels of enthusiasm and competence practised by the teachers.

Linking Te Whaariki and MiNZC

The study demonstrated a definite link between Te Whaariki (Ministry of Education 1996) and MiNZC (Ministry of Education 1992) with every play activity having at least one mathematics strand evidenced.  However, as Carr, Peters & Young-Loveridge (1994) point out, mathematics is not an isolated subject: it is but one part of the whole curriculum, and most of the time is not the focus of the play.  To illustrate this, one child, who was playing on the see-saw, used this activity in a manner that showed she knew how to experiment with weight in order to make the see-saw work for her.  This example also served to illustrate the problem solving underpinnings of both Te Whaariki and the mathematical processes of MiNZC: the child was constructing her own learning based on prior knowledge, understanding, trial and error, communication and experimentation in relation to context.  When she goes to school it is anticipated that this child will use and build upon all these strategies in future mathematics learning.  The kindergarten setting and programme based on Te Whaariki (Ministry of Education 1996) offers children time to choose, observe, listen, experiment, articulate, reflect, control, interact and work alongside other children and adults in ways that are basic to the play setting within the learning environment.

Teacher disposition to mathematics

From reflection on the ‘learning-by-doing’ displayed by the children a clearer perception emerged of what was being learned and how it was being learned.  Although the children were not taking part in a structured mathematics lesson, what they were in fact engaged in, on each occasion, was a play situation which promoted the basis for more formal learning at a later stage.  Learning almost anything is more effective when it is as contextually authentic as possible, but even more effective when the teacher can use the engagement and involvement aspect to help identify teachable moments in which to extend and cement specific learning.

Many adult acquaintances of the researcher, when spoken to about mathematics and the purpose of this research, spontaneously acknowledged that although they 'coped' at school and have since been able to do 'most' of the everyday calculations required for everyday living, their experience of learning mathematics imbued them with a sort of 'bogey' image of mathematics as a subject.  It seems that while many of the mathematics teachers were known to be good at their subject they were not always good at imparting knowledge.  It is probable that students who thought they were weak in mathematics made little progress because their actual abilities had never been identified and developed.  So again, the capacity of the teacher to indicate his or her enthusiasm for the subject, in terms which relate clearly to the level at which the children are at, is a significant factor in any discussion of teaching and learning mathematics.

It seems a logical corollary, then, that the teaching of mathematical concepts be focused on activities that engage and involve, rather than on more structured pedagogical processes, and certainly at kindergarten level.

Teacher education in mathematics

Throughout this study it became apparent that knowledge is a pre-requisite for effective teaching of mathematics in early childhood.  It is not only student-teachers who need subject education as provided at Auckland College of Education (Haynes, 1999) but also teachers in the field.  Coincidentally, during the study, two colleagues in the researcher's teaching team attended a half-day seminar on mathematics in early childhood education, an outcome of which was a new awareness and focus for the team to work at, discuss, and reflect upon. This may have strengthened the focus of the study and therefore also serves to illustrate that with on-going professional development for teachers in the area of mathematics education, it is possible that a more productive emphasis might well be placed upon mathematics as a programme component in early childhood settings.

Socio-cultural issues in mathematics education

Considering the smallness of the sample in the study no statistical significance can be attached to gender ratios, or to cultural differences.  However it is worthy of note that on this particular session there appeared to be more girls than boys who enjoyed meeting challenges that were actually mathematical in essence.  A third of the sample were of Asian origin, a cultural group believed to be positively oriented towards mathematics.  It is assumed that most Asian children are early imbued with a studious work ethic, regardless of actual or assumed ability.  Certainly the Asian children, on this session, when playing in the kindergarten environment, are always communicating with each other about their play.  Furthermore, observation suggests that it is girls who correct boys when mistakes are made, or who help when guidance is required.  It is of interest to note that, of the three teachers at this particular kindergarten, the teacher who is most aware of mathematical potential was educated in Taiwan.

Conclusion

The findings of this study clearly indicate that the incidence of four-year-old children successfully engaging in the concepts of level one (or even level two occasionally) in MiNZC (Ministry of Education, 1992) is not merely circumstantial and should not be overlooked.  An encompassing question for further investigation, suggested by this research, is whether the mathematical needs of children in the earlier years of their education are being adequately catered for.  As a corollary, now that MiNZC is ten years old, it seems timely to review the document in the light of its significance for early childhood education.  As evidenced in this study, the document does provide an appropriate framework for early childhood mathematics education but it is not often found in kindergartens.  Newly graduated teachers have copies whereas other teachers are required to purchase their own copies.

Throughout the relevant literature, and particularly during the course of the study itself, the most potent implication became the necessity for all teachers to have greater in-depth knowledge and understanding of mathematical content and processes, and to be confident in their use of mathematical language.  This was demonstrated through the researcher, herself: as her awareness of the mathematical significance of what the children were doing increased, so did the extent of her mathematical interpretation of their activity widen.  This led to a growth in enthusiasm and gave a new depth to the researcher’s teaching practice.

Our education system owes it to children to ensure provision of early childhood teachers well educated in mathematics to maximise the children’s learning in what must always be an essential learning area.  This study into early childhood mathematics education proves the point, and if this means that greater provision of professional development for early childhood teachers must be made, then so be it.  

References

Aitken, J. (2000, April). Probability or proof – inference or information. Paper presented to a Teacher Refresher Course Seminar, Dunedin, New Zealand.
Carr, M. (1998). Assessing children’s experiences in early childhood. Final report to the Ministry of Education on the Project for Assessing Children’s Experiences Part A and Part B. Wellington: Research Division, Ministry of Education.
Carr, M (1999). Being a learner:  Five dispositions for early childhood.  Early childhood practice, 1 (1), 81– 99.
Carr, M., Peters, S., & Young-Loveridge, J. (1994). Early childhood mathematics: Finding the right level of challenge. In J. Neyland (Ed.). Mathematics education: A handbook for teachers, Vol. 1 (pp. 271 – 282). Wellington:  Wellington College of Education.
Cullen, J. (1999). Children’s knowledge, teachers’ knowledge: Implications for early childhood teacher education. Australian Journal of Teacher Education, 24 (2), 15 – 25.
Farquhar, S. (1994, month unknown). Quality teaching in the early childhood sector. Paper presented at the New Zealand Educational Administration Society Winter Seminar Programme on Quality Teachers and Quality Systems, Auckland.
Haynes, M. (1999). The mathematical world of the infant and toddler. In Proceedings of the seventh Early Childhood Convention, Vol 2 (pp. 140 – 148). Nelson, New Zealand.
Haynes, M. (2000). Mathematics education for early childhood: A partnership of two curriculums.  Mathematics Teacher Education & Development, 2, 95 – 104.
McInerney, D., & McInerney, V. (1998). What makes effective teachers? Educational psychology: Constructing learning (2nd ed.). Sydney: Prentice Hall.
Meade, A. (1997). Good practice to best practice: Extending policies and children’s minds. Early Childhood Folio 3, 33 – 40.
Ministry of Education. (1992). Mathematics in the New Zealand curriculum. Wellington: Learning Media.
Ministry of Education. (1996). Te Whaariki: He Whaariki Maatauranga mo nga Mokopuna o Aotearoa. Wellington: Learning Media.
Pound, L. (1999). Supporting mathematical development in the early years. Buckingham, UK: Open University Press.
Steffe, L., & Wood, T. (1990).  Transforming children’s mathematics education:  International perspectives,  New Jersey:  Lawrence Erlbaum.
Stone, S. (1995). Wanted: Advocates for play in the primary grades. Young Children, 50 (60), 45-54.

Main Types of Primary School Maths

Over the past couple of years, more and students can be seen to be giving a massive amount of significance to maths since it has a lot to offer in the short as well as the long run. Studying maths at primary school level has a lot of benefits for students as it is their first introduction to maths, through which they learn it and can always continue to opt for it later on as well. Primary school maths has many types and all of those are unique in their own way. While many students tend to not give the subject a lot of importance, they are highly recommended to do so as it is what makes them successful in the long run.

Basic Maths  

The first type of maths which is taught in primary school is the basic one. This actually tends to cover the basics of the subject which students need to be aware about in order to have a good idea about what the subject tends to teach in the first place. Those who know the mathematical basics well are known to actually do exceptionally well in the subject in the near future. The basics are what make primary school maths so important in the first place; therefore, a good amount of attention must always be given while studying these.

Advanced Maths  

Advanced maths comes later on, after the basics have been covered in the first place. This type of maths tends to go into detail for the purpose of finding out the answers to many equations as well as questions. A lot of people may find difficulty in studying advanced mathematics since its complex but within a short period of time, it definitely tends to get better and easier as well. As a major type of maths taught in primary school after the basics are completed, this definitely should be given a lot of consideration by students and it must most definitely be taught well by the teachers.

Theoretical Maths

Similarly, another type of maths which is taught in the primary school is theoretical maths. This actually is one of the most interesting types of the subject which really have a lot to offer to all those who wish to learn everything there is about the subject. It is due to the fact that it covers all the important mathematical theories which are important to be known in order to score well in tests as well as exams, for that matter. Primary school maths these days includes a good amount of theoretical maths, all of which makes it much more fun and interesting for students.

Conceptual Maths

Another significant type of maths that is taught at primary school level is concept maths. In this type of maths, students are taught various kinds of concepts of the subject. The main purpose of introducing this sort of maths to students is to help them gain a good and deep knowledge of mathematical concepts, without which students cannot progress in the process of learning mathematics the way it has to be done.

The Conclusion 

All of these types of maths are currently being taught in primary schools all over the world due to the fact that they tend to help students increase their overall understanding of the complex subject. Maths is unique and enables people to follow many careers in the present times, which is why students have been highly recommended to study it as much as possible right from the beginning and with such types of maths being offered at primary school level, it becomes much easier for them to pursue mathematics related fields without having to face any troubles in the near future.

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Concept Maths – The Significance .

Even though mathematics is exceptionally intricate, it still has enough reasons to convince anyone for studying it in both the short as well as the long run. The world has progressed immensely over the past couple of years and all of this development has been done through maths, which is precisely why it is so important in the first place. The subject has become the core of many high end fields these days that people can eventually choose if they wish after becoming fully acquainted with maths. Concept maths is something allows people to get an insight about the subject and how it can be actually learnt later on.

Selecting Careers

The subject is highly important for anyone who wishes to have a bright future. This is due to the fact that more and more fields these have require maths and those who do not study it or cannot do well in the subject often stay behind as a result. Therefore, having exceptionally good mathematical skills is something that most people need to have if they wish to actually gain success and want to be someone big in a short period of time in the future. For that purpose, high end learning of the subject is required by all costs.

Developing Reasoning Skills

Individuals have also been highly recommended to learn maths due to the fact that it allows them to achieve a higher sense of logic as well as reasoning. These can come in handy in the process of discussing a wide range of different topics and discussions which are crucial in every day’s routine. Hence, mathematics has always been used for the purpose of providing proper base and evidence in matters such as debates and everything as such. With prominent figures that are facts, one can surely use the subject to their advantages at all times and that too, without facing any kind of trouble in the matter.

Development of Deep Analysis

A common reason behind studying concept maths is the fact that it enables people to have enhanced analytical skills. With increased analytical skills, individuals can not only score well in mathematics, but they can also go on to score high in a lot of other subjects in the near future. This is something which cannot be acquired from any other subject and through maths solely can individuals go on to do analysis in different aspects of their lives. Analytical skills can be difficult to achieve but with proper learning and studying of maths, the process is most likely to become easy later on.

Development of Critical Thinking

Another one of the most prominent reasons for studying concept maths is the fact that it enables people to develop a good amount of critical thinking which helps them overcome a lot of obstacles in their daily lives and in the long run as well. With increased critical thinking, people can actually achieve a lot in their lives and this has been fully revealed through different surveys that have shed light on the fact that studying this kind of maths eventually does enhance the critical thinking power so many people wish to achieve in the present times.

Concept Maths – Is it worth studying?

After all that this kind of mathematics has to offer to people, everyone surely needs to study it in order to enhance their chances of a bright future. Not only is the subject great for studying and increasing thinking skills, but it is also best for anyone who wishes to be able to enter fields that require maths. On the other hand, it gives individuals the ability to have increased reasoning and logic, which is another thing that makes this subject stand out from all the other ones that exist these days and have been since the past few decades. 

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Teaching Primary and Preschool Maths Using Multiple Intelligences (PART 2)

Continue from part 1 over here

Achievement Tests

At the end of the first three-week intervention period, pupils took a 25-item short answer review test on “Fractions”. At the end of every sub-topic on “Decimals” within the second six-weeks’ intervention period, pupils sat for a 25-item short answer review test.

Qualitative Data

Pupils’ interviews and teachers’ observations and reflection journals were also used as instruments for the qualitative data collection.

Procedure

The study was quasi-experimental in design and equivalent group post-test only design was adopted. One teacher taught the comparison classes and another teacher taught the project classes from the low and average-ability groups.

All the pupils and teachers involved in the project underwent MI diagnostic testing. The teachers were briefed on the findings and how it can help them to improve the way they learn and the way they help the pupils to learn. The project group teacher was given her class’s MI profile which showed the detailed intelligence variability within the class. This would help her to design and customize her Mathematics lessons to cater to the dominant multiple intelligences of the pupils in her two project classes.

Table 3 shows the results from the MIDAS Questionnaire which summarizes the MI profile of all the pupils. It indicated that pupils have all the eight multiple intelligences in almost equivalent dominance. The naturalistic intelligence was the strongest intelligence overall. All of the pupils’ intelligences were above the 50^th percentile.

Scale	Natural	Musical	Spatial	Ling	Logical	Kin	Inter	Intra
Mean	55.9	54.1	53.8	53.8	53.1	52.9	52.0	50.8
SD	16.4	14.0	14.7	14.2	13.4	14.7	15.0	14.4

Table 3: Main Scale Means (N= 140)

Ability Group	Low-Ability Group		Average-Ability Group
Multiple Intelligence	Project (N=30)	Comparison (N=32)	Project (N=38)	Comparison (N=40)
Musical	56.4 (12.1)	56.9 (14.7)	54.4 (12.4)	55.7 (16.1)
Kinesthetic	56.8 (11.4)	50.1 (14.2)	52.2 (15.9)	57.5 (14.5)
Logical	56.2 (12.4)	44.6 (13.3)	54.5 (14.0)	56.2 (12.8)
Spatial	58.8 (12.3)	52.6 (15.3)	54.2 (16.2)	56.0 (15.1)
Linguistic	53.3 (13.7)	51.0 (17.0)	54.8 (15.1)	57.2 (13.3)
Interpersonal	54.5 (13.1)	49.4 (16.4)	52.4 (17.0)	54.0 (14.3)
Intrapersonal	52.4 (12.1)	45.0 (12.5)	51.2 (16.1)	54.4 (14.7)
Naturalist	56.4 (16.7)	52.1 (16.4)	58.3 (17.9)	57.3 (15.6)

Table 4: Mean Score and Standard Deviation of Class MI Profile

Table 4 shows the MI profile of each of the project and comparison classes. The comparison group teacher was not given the results of his class’s MI profile. He was to carry out his Mathematics lessons using the traditional method of teaching.

The instruction for the two groups during the three-week treatment, varied in the following ways. The comparison group was taught the traditional method of “drill and practice”. The project group was taught the MI lessons daily where pupils were engaged in activities that encompassed all the eight intelligences. Pupils were taught using colourful and attractive visuals on power-point slides and were engaged in some of the following activities:

·         logic problems, reciting rhymes, raps and jingles

·         singing songs on mathematical concepts, constructing models, posters and number lines,

·         playing board games, “Bingo” and “Uno”

·         handling real life authentic manipulatives

·         working in pairs and groups

·          brainstorming and presenting their project work

·         Reflections on the day’s lesson in their journals.

The MI infused lessons on “Fractions” were crafted by the project group teachers. The comparison group teacher was not involved in the crafting the MI lessons so as to reduce threats to internal validity of the research project. At the end of the three-week treatment sessions, both groups were administered a review test on “Fractions”. The results from this post assessment would determine if the project group achieves a higher mean score than the comparison group. Fifteen pupils were selected at random from the project group to be interviewed to get their feedback on their MI infused lessons.

In the second semester, both the project and comparison groups were taught “Decimals” through MI infused lessons. The comparison group teacher was given his class’s MI profile which showed the detailed intelligence variability within the class prior to the six-week MI intervention. This would help him to design and customize his Mathematics lessons on “Decimals” to cater to the dominant multiple intelligences of the pupils. The pilot group teacher and the comparison group teacher crafted sixteen MI infused lessons on “Decimals”. Both groups were administered a series of four review tests. The results from these review assessments would reveal if the project group achieve a higher mean score than the comparison group due to the longer exposure to MI. Five pupils were selected at random from each class to get their feedback on their MI infused lessons. A focus group discussion among the project teachers was also conducted to get their feedback on the whole project.

PETALS^TM was also administered before and after the intervention period. Post-test results of the project group would reveal if there is an increase in the level of engagement among pupils who are taught Mathematics using the MI strategies and if the longer exposure to MI has a positive impact on pupils’ engagement, motivation and attitude in the learning of Mathematics.

Results

Measure	Mean (SD)		Effect Size
	Pretest	Post-test
PETALSTM Scale
Pedagogy	69.6 (16.6)	76.1 (15.8)	0.39
Experience of Learning	64.0 (19.3)	68.8 (18.5)	0.25
Tone of Environment	70.7 (13.7)	70.8 (19.5)	0.01
Assessment for Learning	67.1 (15.6)	73.8 (17.7)	0.43
Learning Content	66.3 (19.2)	75.6 (17.7)	0.48
Engagement Scale
Affective Engagement	76.4 (17.7)	81.1 (15.0)	0.31
Behavioural Engagement	75.4 (15.1)	78.1 (18.2)	0.18
Cognitive Engagement	72.4 (16.9)	77.0 (15.8)	0.27

Table 5: Mean comparison on pretest and post-test survey of the project group (N=68)

Table 5 shows results of engagement level among the two project groups. The results revealed a small to moderate effect size for Pedagogy, Experience of Learning, Assessment for Learning and Learning Content. The intervention had a higher impact especially on Assessment for Learning, and Learning Content.

The following graph shows the results from the review test on “Fractions”. There is a difference of 12.0 in favour of the project group. Thus, it may be concluded, with some degree of reservation, the MI intervention has a significant impact on the higher achievement among the project group pupils. Results indicated that the MI intervention seemed to have a greater impact on the low-ability pupils.

 

  

The following graph shows the results from the review tests on “Decimals”. There is a difference of 15.0 in favour of the project group. Thus, it may be concluded that a longer exposure to the MI intervention has a positive impact on the higher achievement among the pupils who were taught through MI strategies for nine weeks as compared to the comparison group pupils who were taught through MI strategies for only six weeks. Results also indicated that the MI intervention has a greater impact on the low-ability pupils.

 

Table 7 shows the motivational and attitudinal levels of the comparison and project groups. For all the ten items, the project group scored higher than the comparison group. This suggests that a longer exposure to the MI intervention has a positive impact on the motivational and attitudinal levels of the project group pupils who were taught through MI strategies for nine weeks as compared to the comparison group pupils who were taught through MI strategies for only six weeks. Results also suggest that the pupils were more influenced by exciting, interesting and challenging lessons.

Table 7: Comparisons on motivational and attitudinal level means

No.	Item	Project group	Comparison group	Effect size
F1	I am excited about learning.	85.8 (17.4)	72.5 (22.1)	0.60
F2	I am interested in what is being taught.	84.1 (20.5)	69.6 (23.2)	0.61
F3	I like the subject.	83.1 (20.0)	74.1 (24.4)	0.37
F4	I like doing the activities.	83.2 (21.7)	75.9 (23.2)	0.31
F5	I want to learn more about this subject.	81.7 (18.0)	73.5 (24.7)	0.33
F6	I look forward to the lesson.	84.9 (22.2)	74.2 (21.1)	0.51
F7	I like learning because what I learn in class is useful.	79.0 (24.3)	70.0 (27.2)	0.33
F8	I will keep on trying even if the task is difficult.	79.8 (20.0)	69.7 (24.2)	0.42
F9	I like the challenging work given to us.	79.6 (22.5)	66.0 (27.5)	0.49
F10	I like learning because I can choose the task that I do best.	77.0 (22.6)	64.3 (25.8)	0.49

In addition to the quantitative data, feedback from the project group affirmed the improvement in attitude and the high motivation experienced by pupils from the MI infused lessons. Below is a blog entry by a pupil:

• “We sang a lot of songs about decimals and fractions. It is very fun and interesting learning decimals and fractions. Our teacher teaches us different types of methods and using [attractive] power point [slides] to teach our class. I love Maths! It is really fun to learn! All the questions [are] like solving mystery cases! We also played Maths games to learn. Our teacher teaches us Maths in very fun ways. I love to play more Maths games and learn more about Maths! The Problem Sums are really challenging! Maths is Fun!”

Feedback from the project teachers further affirmed the improvement in attitude and the high motivation observed in pupils through the MI infused lessons. Below is a teacher’s reflection:

• “I have seen for myself how planning a lesson that involves multiple intelligences actually makes the lessons more exciting for the pupils. Pupils can relate better, recall the learning points better, and on the whole, they are more motivated, even to do homework. By getting pupils involved through activities, songs, stories, and using powerpoint slides packed with cute pictures and animations, pupils actually looked forward to learning. This is true “Teach Less, Learn More” in action.”

Discussion and Conclusion

Based on the analysis of the data presented, it is seen that the MI intervention in the area of Mathematics has made positive contributions for the pupils’ engagement, motivation, attitude and achievement towards the learning of Mathematics. Pupils’ and teachers’ reflections support the statistical findings.

The findings obtained from this study, resembles other studies which evaluate MI instructional approach for the pupil success and attitudes. In a study by Cluck and Hess (2003), results showed improved assignment completion, class participation and engagement of learners using MI. Bednar, Coughlin, Evans and Sievers (2002) showed an increase in pupil motivation and positive attitude through the use of MI. In Douglas, Burton and Reese-Durham (2008), results showed considerable increase in academic performance on pupils taught through MI compared to those taught using the traditional method.   Three of the four improvements were observed: improved academic performance, greater impact on the low-ability pupils and behaviour improvements namely on pupils’ attitude and motivation in learning of Mathematics. Discipline problems tend to disappear, as reflected by the project teachers, when pupils are excited about learning in a fun filled lesson.

The success of the project led to a refinement of the prototype and an emergent model for “Teaching Mathematics through Multiple Intelligences” in West View. By 2010, all teachers were involved in infusing MI strategies in their Mathematics lessons. The significant improvement in the school’s Math PSLE results, an increase in percentage pass from 66.4% in 2009 to 81.1% in 2010, indicates that MI has positive impact in pupils’ academic performance. Pupils who were taught Mathematics through MI over three years (2008-2010) produced better PSLE scores than pupils who have not been taught through MI.

In closing, the most beneficial aspect of our research is that it takes into consideration human differences within the classroom and teaches the subject matter in a variety of ways appealing to all learners.

More preschool, Primary school maths experts on creative maths and Heuristics Maths, click here.

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