Measuring Construct Validity and Students’ Mathematical Creative

Thinking Skills

Kadir

and Irna Rahmawati

Department of Mathematics Education, Universitas Islam Negeri Syarif Hidayatullah Jakarta

Keywords: Construct validity, mathematical creative thinking skills, confirmatory factor analysis.

Abstract: This study aims to measure construct validity tests of mathematical creative thinking skills (MCTS) and

analyze students' MCTS. This research was conducted at a Junior High Schools in the city of Bekasi. This

study was a survey involving 180 students as participants. Data analysis uses confirmatory factor analysis

(CFA) and path analysis. The results revealed that: (1) Tests of MCTS are valid and consistently measured

through fluency, elaboration, flexibility, and originality constructs; (2) Construct reliability of the fluency

indicator is 0.952, elaboration of 0.976, flexibility of 0.622, and originality of 0.710; (3) Overall the average

student's MCTS is 50.27 on a scale (0-100), where female students are 61.45 and male is 49.54.

Achievement the highest MCTS of students is obtained in the flexibility indicator of 68.08 then the fluency

is 66.95, elaboration is 34.30, and the lowest is the originality indicator 31.76; (4) Students' MCTS on the

fluency indicator has an indirect effect on the indicator of originality through moderating indicators of

elaboration and flexibility. The conclusion of this study is that MCTS are measured from indicators of

fluency, elaboration, flexibility, and originality. The overall MCTS of students is still relatively low, where

female students are quite good and higher than male students. The ability to solve problems in the

originality indicator is the core of MCTS.

1 INTRODUCTION

The intellectual factor needed to develop

competitiveness in the industrial revolution era 4.0 is

the ability to think creatively. It is included in the

category of high-level thinking skills (HOTs).

Educational institutions are the most conducive

place to develop curricula that can produce creative

and competitive graduates. (Saini, 2015), argued that

the development of the 2013 curriculum, strives to

improve the quality of education to produce

graduates who are creative and able to face future

challenges. The development and formation of

individual creativity potential must be integrated in

the curriculum content. Furthermore, (Sternbergn,

2001) and (Sternbergn & Lubart, 2000) suggested

that individual creative potential will be latent if not

developed and formed.

Mathematics as part of the curriculum plays an

important role in fostering students to have creative

thinking skills. It is a way or method of thinking and

is taught to build the mindset. Moreover, reasoning

of students in solving problems critically, logically

and precisely.

The vision of learning mathematics are: (1)

directing understanding of mathematical concepts

and ideas needed to solve mathematical and other

scientific problems, (2) providing opportunities for

developing logical, systematic, critical and careful,

creative reasoning abilities , fostering self-

confidence, and a sense of beauty towards the nature

of mathematics (Hendriana & Sumarmo, 2014).

Mathematical creativity is defined as a

framework of mathematical knowledge is the ability

to solve problems or to develop thinking in a

structure, taking into account the logic-deductive

nature that is typical of the discipline, and the

concepts produced. Because the definition is related

to originality and usability, the definition of

mathematics (Kadir, Lucyana, & Satriawati, 2017).

Mathematical creativity at a professional level,

defined as: 1) The ability to produce original works

that significantly expand the body of knowledge; 2)

The ability to open new questions for other

mathematicians; 3) Processes that produce unusual

and profound solutions to given problems or analog

problems; 4) Formulation of questions and / or new

Kadir, . and Rahmawati, I.

Measuring Construct Validity and Students’ Mathematical Creative Thinking Skills.

DOI: 10.5220/0009914406670674

In Proceedings of the 1st International Conference on Recent Innovations (ICRI 2018), pages 667-674

ISBN: 978-989-758-458-9

667

possibilities that allow old problems to be

considered from a new perspective (Sriraman, 2005)

Creative thinking includes aspects of cognitive,

affective, and metacognitive skills. The aspect of

cognitive skills contains the ability: identify

problems, compose different questions, identify

relevant and irrelevant data, generate many ideas

(fluency), different ideas (flexibility), new ideas,

change old mindsets and habits, compose new

relationships and renew plans or ideas (Siswono,

2008). The characteristics of creative thinking

abilities, includes: 1) Fluency, namely the ability to

produce many ideas, solve problems or questions; 2)

Flexibility, namely the ability to produce many

varied and different ways; 3) Originality, namely the

ability to think in new ways or with unique

expressions and unusual thoughts from thoughts that

are clearly known; 4) Elaboration, namely the ability

to detail an object, idea, or situation (Siswono,

2008). Based on this definition, it can be concluded

that the ability to think creatively in mathematics

learning which later became known as mathematical

creative thinking skills (MCTS) is an ability that

reflects fluency, flexibility, and originality in

thinking, as well as the ability to elaborate an idea in

solving mathematical problems. Thus, the indicator

of MCTS are fluency, elaboration, flexibility, and

originality.

But in reality, MCTS Indonesian students have

not been reached maximally. The results of an

international study of the 2015, Program for

International Student Assessment (PISA) showed

that only about 10% of Indonesian students were

able to answer level 4, 5, and 6 tests. Characteristics

of tests at level 4, 5, and 6, contained questions

which requires the ability to construct, express

explanations and compile arguments based on

interpretation. Work in complex situations, identify

constraints, choose, compare, and evaluate problem

solving strategies, use broad reasoning, reflect,

formulate and express interpretations and reasoning.

Think of high-level mathematics and put it right

about their findings, arguments, and accuracy in the

original situation (PISA, 2015). Furthermore, the

results of Fardah's research revealed that the

achievement of MCTS of elementary and secondary

school students is still in the low category, which is

46.67% (Fardah, 2012).

Some of the efforts to improve students’ MCTS,

are in providing learning interventions through work

on non-routine problem tests. Learning evaluations

that involve students in completing non-routine tests

must be presented in class. According to Novita et

al., (Novita, Zulkardi, & Hartono, 2012) that one of

the factors causing low scores obtained by students

on the PISA test is the test material and international

standardized test from PISA not yet taught in class.

Besides that most tests in the evaluation process are

still at a low level. Therefore, the mathematical

problem solving test formulated in PISA can be

adapted to develop MCTS tests.

Several recent studies in Indonesia are related to

the development of students’ MCTS instruments

(Fitriani & Yarmayani, 2018) (Fitriani &

Yarmayani, 2018) (Fitriarosah, 2016) (Moma,

2015). Generally this research is a development

research with validity analysis, reliability,

discriminating index, and item difficulty level. The

study has not developed and measured the construct

through the Confirmatory Factor Analysis

procedure. Almost no research has specifically

explained the theoretical constructs of the MCTS

test empirically. Therefore, this study aims to: (1)

measure the construct validity of MCTS tests, and

(2) analyze students' MCTS.

2 METHOD

This study was a survey conducted in 6 junior high

schools (SMP A, SMP B, SMP C, SMP D, SMP E

and SMP F) in the city of Bekasi involving 180

students (male = 98, female = 82) as participants. A

total of 30 students were taken randomly from each

school. The MCTS test developed in the form of an

essay consists of 11 items, representing fluency

indicators, elaboration, flexibility, and originality.

Representation of items into indicators, including:

fluency (1, 2, 3), elaboration (4, 5), flexibility (6, 7,

8), and originality (9, 10, 11). This study involves

rectangular flat geometry. Before empirically testing

MCTS test items, it was first assessed the feasibility

of expert panelists from the aspect of content and the

accuracy of items measuring indicators.

Furthermore, an assessment of student answers from

the MCTS test results uses a rubric adapted from

Bosch (Bosch, 2008). The rubrics of students'

creative mathematical thinking skills, in Table 1.

Table 1: Rubric of the MCTS Test

Indicator

Score

Descriptors

Fluency

No answer or no relevant

answer

Give an idea that is relevant to

problem solving but the

disclosure is less clear or

wrong.

Provide an idea that is relevant

to problem solving but the

ICRI 2018 - International Conference Recent Innovation

668

completion and disclosure is

incomplete or unclear.

Provide more than one

idea/answer that is relevant to

solving the problem but the

solution is unclear.

Provide more than one

idea/answer that is relevant to

problem solving and full and

clear disclosure.

Elaboration

Don't answer or give the wrong

answer.

There is a mistake in expanding

the situation without details.

There is a mistake in expanding

the situation and still not

detailed.

Extending the situation

correctly but not detailed.

Expand the situation correctly

and in detail.

Flexibility

Do not answer or give answers

in one way or more but

everything is wrong.

Give answers in only one way,

there are errors in the

calculation process, that the

results are wrong.

Give answers in one way, the

calculation process and the

results are correct.

Give answers in more than one

way (various) but the results are

wrong because there is a

mistake in the calculation

process.

Give answers in more than one

way (various), the calculation

process of the results is correct.

Originality

Do not give answers or give

wrong answers.

Give answers in their own way

but cannot be understood.

Providing an answer in its own

way, the calculation process is

directed but not completed.

Give answers in their own way

but the results are wrong

because there is a mistake in the

calculation process.

Give answers in their own way,

the calculation process and the

results are correct.

The data analysis technique uses Confirmatory

Factor Analysis (CFA) with Lisrel 88.00 and AMOS

version 20. CFA analysis techniques use SEM

(Structural Equation Modeling) with a measurement

model. Item validity is determined based on the

loading factor test. Empirically an indicator or item

is said to be valid measuring construct if the

estimation results of loading factor () > 0.5 or has a

t-test statistical value with a p-value < 0.05.

An indicator is said to be dominant if it has 

≥

0.70 (Hair, Black, Babin, & Anderson, 2010).

Determination of Composite Reliability is based on

a composite internal consistency of construct

measurement indicators. In general a construct,

unidimensional, precise, and consistent can be

measured by indicators / items, if: (a) the model is fit

with the data, (b) Loading factor () is significant

above 1.96 or () > 0.50 and (c) Estimation of the

coefficient of CR (Composite Reliability) ≥ 0.70 and

VE (Variance Extracted) ≥ 0.50 (Hair et al., 2010).

The Construct Reliability (CR) and Variance

Extracted (VE) formulas are as follows:

,=and=

VECR





































































here:



= loading indicator factor to - i,



= indicator variance error to – i

= number of indicators in the model

3 RESULTS AND DISCUSSION

CFA analysis technique aims to estimate the

accuracy of the items that measure factors that have

been compiled based on theoretical constructs.

Through CFA analysis, the construct estimates are:

(1) fluency, (2) elaboration, (3) flexibility, and (4)

originality.

3.1 Construct Validity

The results of estimation of loading factor in Table

Table 2: Results of estimated loading factor with CFA

Factors

Factor

observe

table

Decisi

Fluency

0.986

18.408

1.96

Sig

0.961

17.409

1.96

Sig

0.978

18.135

1.96

Sig

Elaboratio

0.986

17.571

1.96

Sig

0.990

17.681

1.96

Sig

Flexibility

0.277

2.108

1.96

Sig

0.359

2.270

1.96

Sig

0.065

0.576

1.96

Non

Sig

Originalit

0.713

7.527

1.96

Sig

0.319

3.616

1.96

Sig

0.473

5.449

1.96

Sig

Measuring Construct Validity and Students’ Mathematical Creative Thinking Skills

669

Based on the results of the analysis in Table 2, it

shows that all items except item number 8, have t-

observe > t-table = 1.96. This means that all items of

MCTS except item number 8 are declared valid

measuring constructs of fluency, elaboration,

flexibility, and originality. Thus, the MCTS

consisted of 10 items (valid) and four indicators,

namely fluency consisting of 3 items with loading

factors (0.986; 0.961; 0.978), elaboration consisting

of 2 items with loading factors (0.986; 0.990),

flexibility consisting of 2 items with loading factors

(0.277; 0.359) and originality consisted of 3 items

with loading factors (0.713; 0.319; 0.473). The

findings of this study, in contrast to the findings of

(Fitriarosah, 2016) about the MCTS, found a set of

MCTS test consisting of 4 valid items, the reliability

of good categories, also had a good discriminating

index and varying degrees of difficulty.

Visually loading factors from the MCTS test are

presented in the path diagram in Figure 1.

Figure 1: Path Diagram of Loading Factor

The path diagram of the factor loading estimation

results from the MCTS test with the t-test is

presented in Figure 2.

Figure 2: Path Diagram of the Loading Factor with the t-

test

3.2 Reliability

The reliability estimation results from the MCTS test

are presented in Table 3.

Table 3: Results of MCTS test reliability estimates

Factor

Number

of items

Construct

Reliability

Varians

Extracted

Fluency

0.952

Elaboration

0.976

Flexibility

0.622

0.503

Originality

0.710

0.578

Total

0.815

0.752

From the results of the analysis in Table 3, the

overall CR value is 0.815 and VE is 0.752. By using

criteria from estimates for CR ≥ 0.70 and VE ≥

0.50, this finding reveals that the construct of the

test, right, and consistently measuring MCTS or

having internal consistency is good (Hair et al.,

2010). This finding is similar to La Moma's finding

that the MCTS test reliability is 0.840 but uses the

Cronbach Alpha formula (Moma, 2015).

3.3 Test of Goodness of Fit Statistics

Testing fit models aimed at studying how precise the

measurement model proposed can fit the research

data. The results of the analysis relating to the size

of the model Fit, are presented in Table 4.

ICRI 2018 - International Conference Recent Innovation

670

Table 4: Summary of fit model indication

Goodness of

Fit

Indicators

Result

Judge

Chi-Square (p)

p > 0.05

p = 0.051

fulfilled

RMSEA

< 0.05

0.047

fulfilled

The analysis in Table 4, shows that indicators

Goodness of Fit were fulfilled. This means that the

conceptual model of the proposed MCTS test is fit

with the data.

3.4 Mathematical Creative Thinking

Skill (MCTS)

Students' overall mathematical creative thinking

skills (MCTS) are presented in Table 5.

Table 5: Descriptive statistics of students' MCTS

Valid

180

Missing

Mean

50.27

Median

48.00

Mode

Std. Deviation

10.272

Variance

105.524

Skewness

.525

Std. Error of Skewness

.181

Kurtosis

.206

Std. Error of Kurtosis

.360

Range

Minimum

Maximum

It can be seen from Table 5, as a whole from 180

students as respondents, indicating that students'

mathematical creative thinking skills are still low in

level.

Visually the distribution of students' MCTS data,

as a whole is presented in Figure 3. Based on Figure

3, it is found that the MCTS data distribution has a

tendency to collect below the empirical average.

This means that the MCTS data distribution is

grouped below the average. Thus the ability of

MCTS students is still relatively low.

Figure 3: Frequency Histogram of students’ MCTS as a

whole

Students’ MCTS data by gender score in Table 6.

Table 6: Data on sudents’ MCTS

Statistics

Mathematical Creative

Thinking Skills (MCTS)

Male

Female

Total

180

Std. Deviation

1274

13.32

10.27

Mean

49.54

61.45

50.27

Median

48.75

49.88

48.00

Modus

50.83

52.50

48.00

Minimum

Maximum

The results of the analysis in Table 6, show that

from 180 students as respondents, an average score

of 50.27, a maximum value of 78 and a minimum of

30, a median of 48.00, Mode 48, and Std. Deviation

10.27. This finding reveals that the ability of

students' MCTS is still relatively low.

The findings of this study, similar to the research

of (Fitriani & Yarmayani, 2018) who developed the

MCTS rubric of students of Senior High School,

found that the classification of highly creative

abilities (75-96) was 0%, creative (50-74) as much

as 39.13 %, quite creative (25-49) of 60.86%, and

less creative (0-24) as much as 0% [12]. From Table

IV, also obtained the average MCTS score of male

students was 49.54 and female was 61.45. This

means that MCTS female students are higher than

male students. The findings of this study are in

accordance with the opinion of Krutestkii (Nafi’an,

2011), explaining that men are superior in reasoning,

women are superior in precision, accuracy, and more

careful in thinking. Men have better mathematical

and mechanical abilities than women, this difference

Measuring Construct Validity and Students’ Mathematical Creative Thinking Skills

671

is not apparent at the basic level but becomes more

apparent at a higher level.

Furthermore, student scores on each indicator

from MCTS based on the school in the Table 7.

Table 7: average student scores for each MCTS indicator

and school

Schoo

Average students' MCTS for each

indicator

Mean

Fluency

Elabor

Flexi

Origin

71.17

42.70

64.33

29.93

52.03

61.90

29.30

69.83

24.70

46.43

70.17

30.60

69.03

33.27

50.77

75.90

48.63

83.60

52.50

65.16

63.00

26.93

63.57

26.63

45.03

59.53

27.63

58.13

23.50

42.20

Mean

66.95

34.30

68.08

31,76

50.27

Based on the results of the analysis in Table 7,

the students' ability score on the fluency indicator is

66.95, elaboration is 34.30, flexibility is 68.08 and

originality is 31.76. Research findings confirm that

flexibility is an indicator that is better than fluency,

elaboration, and originality. The fluency indicator is

the ability to provide many answers, then the

elaboration indicator, namely the ability to write

information that is known to the problem. While the

flexibility indicator is the ability to provide

alternative ways to solve problems, and the

originality indicator is to produce unusual or unique

answers according to quadrilateral geometry. The

findings of this study are somewhat different from

the findings of (Fatimatuzahro & M Budiarto, 2014),

who reported that students with high mathematical

abilities had better creative thinking skills on

indicators of fluency and elaboration, while students

with moderate math ability were only better at

fluency indicators and students with low abilities did

not show creative thinking skills.

3.5 Test the Influence Hypothesis

among the MCTS Indicators

Hypothesis test results of the influence between the

MCTS indicators in Table 8.

Table 7: Results of influence among the MCTS indicators

Influence among

indicator

Est

S.E.

C.R.

Elaboration 

Fluency

.235

.054

3.234

.001

Flexibility  Fluency

.053

.070

.700

.484

Flexibility 

Elaboration

.166

.093

2.201

.028

Influence among

indicator

Est

S.E.

C.R.

Originality 

Flexibility

.200

.074

2.708

.007

Originality 

Elaboration

.052

.094

.689

.491

Originality  Fluency

.080

.069

1.068

.285

Based on the analysis results in Table 8, it shows

that the indicators: (1) fluency has an influence on

the elaboration indicator (p = 0.001 <0.05); (2)

fluency has an influence on flexibility (p = 0.484>

0.05); (3) elaboration has an influence on flexibility

(p = 0.028 <0.05); (4) flexibility has an influence on

originality (p = 0.007 <0.05); (5) elaboration has no

effect on originality (p = 0.491> 0.05); (6) fluency

does not have an influence on the originality

indicator (p = 0.285> 0.05). Thus the hierarchy of

influence according to the MCTS indicator starts

from the lowest position of fluency, elaboration,

flexibility and the highest position on originality.

Visually the relationship between MCTS items

and indicators in Figure 4.

Figure 4: Relationship between test items and indicators

The research findings revealed that the students'

MCTS on the fluency indicator had a positive effect

on students' ability on the elaboration indicator.

Thus the higher the ability of students in the fluency

indicator, the higher the ability of students in

elaboration skills. This finding shows that the ability

to provide many ideas in determining the area and

circumference of the rectangle supports the students'

ability to enrich the detailed information of

rectangular Geometry problems. While the ability of

students on the elaboration indicator has a positive

effect on students' ability in flexibility. This means

that the ability of students on the elaboration

indicator determines students' abilities on flexibility

indicators. Thus the higher the student's ability in the

elaboration indicator, the higher the student's ability

ICRI 2018 - International Conference Recent Innovation

672

in flexibility. This finding confirms that students'

ability to detail details of information or data from a

rectangular flat geometry problem helps students

make several different interpretations in solving

rectangular-related problems.

Furthermore, the ability of students on the

flexibility indicator has a positive effect on students'

abilities in the originality indicator. This means that

the ability of students on the flexibility indicator can

actually explain students' abilities in the originality

indicator. This finding describes that the ability to

produce ideas, answers or questions that vary, can

see problems from different points of view, and are

able to find many alternatives or different directions

from the problem of rectangular geometry to a

capacity to express new and unique things, thinking

of unusual ways, and making unusual combinations

of rectangular elements.

The findings of this study also provide a

distinctive and novelty related to the MCTS test

measuring indicator, namely that through path

analysis between indicators, we find a hierarchy of

abilities as a sequence of abilities that starts from the

fluency indicator then elaboration, flexibility and

ends in the originality indicator as the highest ability

in creative thinking.

The following are examples of questions and

student answers to the originality indicator.

"Pay attention to the right triangle below. The

BR line is parallel to the PQ line with point P as the

midpoint of the BC line. Determine the area to be

shaded? "

6 cm

8 cm

Students' answers to the questions above are made in

two ways, namely:

Answer 1:

By constructing the flat trapezium into a rectangle

and parallelogram.

From this picture the area of shading = 1/2 the area

of parallelogram, while area of parallelogram = area

of rectangular area - 2 area of triangle.

Area of parallelogram = (6 x 8) –2 (½(4 x 6)) =

48 – 24 = 24 cm

. Dhus area of shading = 1/2 area

of parallelogram = ½ x 24 = 12 cm

Answer 2:

Draw a line from one of the trapezium points to

another.

It is seen that the area of the trapezium is formed of

several triangles. Dhus area of shading = 1/2 the area

of ABC right triangle = ½ x ½ (6 x 8) = ¼ x 48 = 12

Thus the core of MCTS is developing the ability

to focus on the originality indicators. As with

Sriraman's definition, that mathematical creativity is

the ability to produce original works that

significantly extends the body of knowledge

(Sriraman, 2005). To maximize MCTS in the

originality indicator, the flexibility capability is

needed. While increasing flexibility is determined by

fluency and elaboration abilities. This finding

confirms that the role of fluency indicator capability

on originality can be mediated by indicators of

elaboration and flexibility. We believe that these

findings are new findings that complement previous

studies related to the ability to think creatively in

mathematics learning.

4 CONCLUSION

Based on the findings and discussion, it can be

concluded that the MCTS test is valid and

consistently measured through constructs or

indicators of fluency, elaboration, flexibility, and

originality. Overall, the MCTS test construct has an

internal consistency of 0.815 or a very good

Measuring Construct Validity and Students’ Mathematical Creative Thinking Skills

673

category. MCTS test consists of 10 items and four

indicators, namely fluency consisting of 3 items with

loading factors (0, 986; 0.961; 0.978) and construct

reliability of 0.952; elaboration consists of 2 items

with loading factors (0.986; 0.990) and construct

reliability of 0.976, Flexibility consists of 2 items

with loading factors (0.277; 0.359) and construct

reliability of 0.622, and originality consists of 3

items with loading factors (0.713; 0.319; 0.473) and

construct reliability of 0.710.

The overall MCTS of students is still relatively

low, which is an average of 50.27 on a scale (0-100).

Achievement the highest MCTS of students is

obtained in the flexibility indicator of 68.08; then the

fluency is 66.95, elaboration is 34.30, and the lowest

is the originality indicator 31.76. The average MCTS

of female students is 61.45 and male students are

49.54. Thus, MCTS of female students are quite

good and higher than male students. The influence

of ability on the fluency indicator on originality is

mediated by indicators of elaboration and flexibility.

The ability to solve problems in the originality

indicator is the core of students' creative thinking

ability. Therefore, it is suggested that to improve

students' creative thinking skills students should

begin gradually from problems that measure fluency

indicator abilities then elaboration, flexibility and

end with originality. To maximize students' ability to

think creatively mathematically on the originality

indicator, the best performance is needed on the

flexibility indicator. While increasing flexibility is

determined by fluency and elaboration abilities.

REFERENCES

Bosch, N. (2008). Rubric for Creative Thinking Skills

Evaluation. Kansas: KCCL.

Fardah, K. D. (2012). Analisis Proses dan Kemampuan

Berpikir Kreatif Siswa dalam Matematika Melalui

Tugas Open-Ended. Jurnal KREANO FMIPA UNNES,

Fatimatuzahro, & M Budiarto. (2014). Identifikasi

Kemampuan Berpikir Kreatif Siswa SMP dalam

Menyelesaikan Soal Matematika Open-Ended Ditinjau

dari Perbedaan Kemampuan Matematika. Jurnal

MATHEdunesa Jurusan Matematika UNESA, 3, 85–

89.

Fitriani, S., & Yarmayani, A. (2018). Pengembangan

Rubrik Berpikir Kreatif Siswa Menengah Atas Dalam

Menyelesaikan Masalah Matematika. Jurnal

Mosharafa, 7.

Fitriarosah, N. (2016). Pengembangan Instrumen Berpikir

Kreatif Matematis Untuk Siswa SMP. Prosiding

Seminar Nasional Pendidikan Matematika, Malang:

Universitas Kanjuruhan Malang.

Hair, J. F., Black, W. C., Babin, B. J., & Anderson, R. E.

(2010). Multivariate data analysis (7th ed.). New

Jersey: Pearson Prentice Hall.

Hendriana, H., & Sumarmo, U. (2014). Penilaian

Pembelajaran Matematika. Bandung: PT Refika

Aditama.

Kadir, Lucyana, & Satriawati, G. (2017). The

Implementation Of Open-Inquiry Approach To

Improve Students’ Learning Activities, Responses,

and Mathematical Creative Thinking Skills. Journal

on Mathematics Education, 8, 103–114.

Moma, L. (2015). Pengembangan Instrumen Kemampuan

Berpikir Kreatif Matematis untuk Siswa SMP. Delta-

Pi:Jurnal Matematika Dan Pendidikan Matematika, 4.

Nafi’an, M. I. (2011). Kemampuan Siswa Dalam

Menyelesaikan Soal Cerita Ditinjau Dari Gender Di

Sekolah Dasar. Prosiding Seminar Nasional

Matematika Dan Pendidikan Matematika, Jurusan

Pendidikan Matematika FMIPA UNY, 573 – 574.

Novita, R., Zulkardi, Z., & Hartono, Y. (2012). Exploring

Primary Student’s Problem Solving Ability by Doing

Tasks Like PISA’s Question. IndoMS, J.M.E, 3(2),

133–150. https://doi.org/10.1007/s13398-014-0173-

7.2

PISA. (2015). No Titl. Results Excellence and Equity in

Education, 1.

Saini, R. A. (2015). Inovasi pembelajaran. Jakarta: Bumi

Aksara.

Siswono, T. Y. E. (2008). Model Pembelajaran

Matematika Berbasis Pengajuan Masalah dan

Pemecahan Masalah untuk Meningkatkan

Kemampuan Berpikir Kreatif. Surabaya: Unesa

University Press.

Sriraman, B. (2005). Are giftedness & creativity

synonyms in mathematics? An analysis of constructs

within the professional and school realms. The Journal

of Secondary Gifted Education, 17, 20–36.

Sternbergn, R. J. (2001). Wildson, Intelligence, and

Creativity Synthesized. New York: Cambridge

University Press.

Sternbergn, R. J., & Lubart, T. L. (2000). The Concept of

Creativity: Prospects and Paradigms. In R.J.

Sternbergn (Ed.), Handbook of Creativity (pp. 27–39).

New York: Cambridge University Press.

ICRI 2018 - International Conference Recent Innovation

674