Southeast Asian Mathematics Education Journal 

Volume 12, No. 1 (2022) 

 11 

 

Enhancing Mathematics Learning by Integrating Growth Mindset Principles in Ninth-

Grade Supplementary Materials 

1
Christian R. Repuya & 

2
Jedh Esterninos 

1
Bicol State College of Applied Sciences and Technology, Philippines 

2
University of Nueva Caceres, Philippines 

1
crrepuya@astean.biscast.edu.ph 

 

Abstract 

This paper determined the supplementary materials in ninth-grade mathematics which may be 

enhanced to integrate growth mindset principles to improve students’ procedural fluency and 

foster their growth mindset in mathematics. This study employed a descriptive-developmental 

method by administering a quasi-experimental design and mixed-method research approach 

to determine the research questions. The respondents in this study were the 60 ninth-grade 

students at a state secondary high school in the Philippines. The study implemented the 

validated researcher-made procedural fluency test and growth mindset questionnaire in 

determining students’ performance in procedural fluency and mindset in mathematics, 

respectively. Thematic analysis was employed to investigate students’ responses in Focus 

Group Discussions (FGD), informal interviews and learning journals in scrutinising the 

learning experiences and mindsets of the students. Findings displayed that the supplementary 

materials which can be developed in incorporating growth mindset principles were 

motivational activities, reflection activities, and instructional videos. Utilising the developed 

supplementary materials elevates students’ procedural fluency. It influences students to shift 

from fixed mindsets to growth mindsets in mathematics by providing them with significant 

learning experiences that help students enhance a growth mindset. Furthermore, the 

implementation group performed better than the comparison group, particularly with 

developing growth mindsets. The study results are limited to the participants encompassing; 

similar research employing the developed supplementary materials to other learning areas 

with a larger sample is recommended for more generalisable results. 

 

Keywords: growth mindset in mathematics, motivational, procedural fluency, reflection, instructional videos 

 

 

Introduction 

Studying mathematics is tremendously crucial in people’s lives. Mathematics education 

begins in the early stage of education. Its objective is to assist students acquire the 

significance of mathematics applications in the real world by enhancing their cognitive ability 

to recognise forms, patterns, and relationships. However, despite its significance, 

mathematics is still the least preferred and hated subject among students in general, and 

encourages for fewer students than other subjects. It is caused by the students who perceive 

mathematics as a complex subject, particularly following instructions. It results in difficulty 

obtaining the subject and trouble recalling its equations and methods to discover a solution to 

a problem (Gafoor & Kurukkan, 2015). 

Correspondingly, students who possess a negative attitude towards their teachers and 

mathematics also perceive it as boring, and they are not encouraged (Mohapi, 2015). 

Enjoyment and attitude in learning mathematics significantly determine students’ 

performances. Furthermore, the factors influencing the students to like or dislike mathematics 

encompasses students’ social-psychological, environmental, instructional, and abilities 



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

12 

 

factors. Moreover, the teacher’s instructional strategy, institutional sources, weak 

understanding and evaluation approaches, and failure in comprehending directions are the 

factors of failure to pass mathematical examinations (Mazana, Montero, & Casmir, 2019). 

In the Philippines, the international examination results in the Program for International 

Student Assessment (PISA) 2018 also presented a low growth mindset among students 

(Organization for Economic Co-operation and Development (OECD), 2019). 

The PISA 2018 (OECD, 2019) results revealed that only 19% of students in the 

Philippines attained level 2 or higher in mathematics. Only 31% of students in the Philippines 

possessed a growth mindset. As a result, the Philippines performs low in the PISA 

examination, with an average score of only 350 points in mathematics, science, and reading 

during School Year (SY) 2018-2019, which place them in the rank 77
th

 out of nearly 80 

nations (OECD, 2019).  

Unfortunately, the National Achievement Test (NAT) results formulated this global 

performance at the local levels. In the 2012 NAT, the Philippines performed low, with a 

Mean Percentage Score (MPS) of only 46.37 in mathematics. The enhanced performance was 

not acquired compared with the past years (47.82 in 2006 and 50.7 in 2005) and an overall 

rating of 48.57 during SY 2011-2012. This dilemma in mathematics paused threats to the 

future of mathematics education. 

This evidence indicates that the students are not motivated and own a low interest in 

learning mathematics because they possess a low growth mindset. The students believe that 

learning mathematics is complicated as they own low procedural fluency. Procedural fluency 

refers to a student's understanding of procedures, as well as when and how to employ them 

correctly, and also the ability to administer procedures flexibly, precisely, and efficiently 

(Inayah, Septian, & Suwarman, 2020).  

In response, the Department of Education (DepEd) (2020) encourages teachers to design 

lessons, learning materials, and instructional materials to assist students become motivated 

and have elevated understanding of the topics. Mendoza, Caranto, and David (2015) 

recommended that supplementary materials as integrating instructional videos effectively 

acquire the student's interest. Integrating instructional video into teaching/learning is a 

method in teaching which utilises videos that allows teachers to deliver lessons and 

encourage students through video recordings.  

Gieras (2020) asserted that designing engaging instructional videos which encourage 

interactions and engagement to corroborate students’ learning can be a very well effective 

medium for assisting instruction in remote, hybrid, and flipped or blended learning 

conditions. Moreover, Harackiewicz, Smith, and Priniski (2018), when students improve their 

interest in studying mathematics, their motivation in learning is also enhanced. 

In her article, Campbell (2017) argued that success necessitates students to engage in the 

individual growth process. She highlighted on how difficult it might be to be open in 

producing incorrect and altering course all the time. It is normal to be involved to what we 

believe works and what we are accustomed to. She emphasised that in establishing a growth 

mindset, students should educate themselves to identify “deficient” as a shortfall in their 

learning or experience rather than a weakness in their capability. Dweck (as cited in Boaler, 

2013) corroborated that intelligence and smartness could be acquired, and that brain grows 

from training with a growth mindset. 



Christian R. Repuya & Jedh Esterninos  

                    
13 

  

Conley (2014) implemented a growth mindset when providing students feedback, 

elaborating that praising them for intelligence made them less willing to pursue educational 

opportunities because they are anxious about losing their “smart” identity if they experienced 

low. Furthermore, because avoiding academic risks entails avoiding learning, applauding 

students undermines their academic achievement. The researcher employed the power of the 

word “yet” associated with a growth mindset. For instance, in praising students, “your 

sentence structure does not yet match the tone you are attempting to achieve”. The word 

“yet” accepts negative comment while at the same time conveys confidence that the students 

receive shortly (a teacher as this one possesses a growth mindset). 

In addition to giving feedback, allowing students to perform reflective learning activities 

help them aware of their performance. In their study, Weng, Puspitasari, Rathinasabapathi, 

and Kuo (2021) defined reflective learning as activities in facilitating learners’ reflection 

upon their learning experiences. The findings of their study recommend the significance of 

reflective learning to enhance students’ recognition of asking and assessing their learning in 

the class.  

Furthermore, Berger (2017) asserted that students are able to elevate the courage to 

encounter educational and life challenges. He cited one of the secondary schools, which has 

advanced academic courage in the students. As a result, 98% of their students graduated on 

time, and all of the students have been admitted to university. 

The previous studies were beneficial in conceptualising the present study. Compared to the 

previous studies, the present study integrates growth mindset principles in the supplementary 

materials, which become the motivational activities, reflection activities, and instructional 

videos, that are not specifically implemented in the studies cited. Moreover, based on the 

literature and studies displayed, there is a crucial need to conduct this study to enhance 

supplementary materials in accommodating growth mindset principles to enhance students' 

mindset and procedural fluency in mathematics. 

The study was anchored on the following theories. The primary theory of this study is the 

(1) Mindset Theory (2006) and was corroborated by (2) Constructivists Theory (McLeod, 

2019) and (3) Scaffolding theory of Lev Vygotsky (McLeod, 2019). 

Carol S. Dweck is the author of the Growth Mindset Theory. She explained that a mindset 

believes in oneself, and one’s basic qualities. An individual with a fixed mindset believes that 

traits like intelligence, creativity, and ability are predefined and finite. These attributes are so 

established in persons with fixed mindsets that whatever they lack, they remain to be 

inadequate. 

A person with a growth mindset, on the other hand, believes that their natural talents were 

further strengthened via hard work and dedication. These intrinsic traits are merely the 

beginning; the results of success from hard work, study, and perseverance.  

Dweck employed a school setting as an example who explained that fixed and developing 

mindsets emerge differently. Students with a fixed mindset regulate image above all and, as a 

result, disregard the essential learning opportunities if performing poorly or admitting 

mistakes is required. In the classroom, cognitivist teaching approaches strive to help students 

assimilate new material into their existing knowledge while also make them produce the 

required modifications to their current intellectual structure in accommodating the new 

knowledge. 



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

14 

 

According to the scaffolding theory, scaffolding involves adjusting the amount of 

assistance to the intellectual abilities of students. During a teaching session, the extent of 

coaching was modified to fulfil the student's potential level of performance. When a student 

experiences difficulties with a task, further assistance is provided, and as the student 

progresses, less guidance is performed. 

The objective of this study is to enhance students’ mathematics learning by integrating 

growth mindset principles in ninth-grade supplementary materials in one of the junior high 

schools in the Philippines. In particular, it examined the supplementary materials in ninth-

grade mathematics which may be enhanced to integrate growth mindset principles. Moreover, 

it was also performed in determining the effects of employing the ninth-grade supplementary 

materials with growth mindset principles integration in enhancing students’ procedural 

fluency in mathematics and fostering their growth mindset in mathematics. 

This study is deemed essential to students because the findings would convey messages 

that mathematics can be learned by all individuals who are able to learn and appreciate 

mathematics and that their ability is not fixed. For teachers, the findings of the study would 

assist them appreciate the implementation of supplementary materials promoting a growth 

mindset through motivational activities, reflective learning activities, and utilisation of 

instructional videos that make students encouraged, responsible, and possess a robust growth 

mindset in mathematics. In improving growth mindset and procedural fluency among 

students in mathematics, the school administrators, curriculum designers, and textbook 

writers may consider the study's findings in formulating programs, designing curriculums, 

and selecting a framework for writing textbooks respectively. 

 

Methods 

Research Design 

The study employed the descriptive-developmental method using a quasi-experimental 

design. The study also utilised the mixed-method approach of research inquiry. The 

implementation group applies the innovation to determine the effect of utilising the ninth-

grade mathematics supplementary materials with growth mindset integration on students’ 

procedural fluency and mindset in mathematics. The comparison group was implemented for 

the comparison of results which incorporated the textbook and lesson plans provided by the 

department of education without the supplemental materials. 

Below is the study’s design diagram, where    and    are the pretest and posttest of the 

implementation group, respectively. X is the intervention (developed supplementary 

materials integrating growth mindset principles). Meanwhile,    and    are the pretest and 

posttest of the comparison group, respectively, without the intervention: 

 

        X     

             

 

Respondents 

The respondents of the study were purposively selected two classes of one of the public 

secondary high schools in the Philippines, SY 2020-2021. Purposive sampling is a technique 



Christian R. Repuya & Jedh Esterninos  

                    
15 

  

in which the researcher arranges criteria to select members of the population to be in charge 

as respondents of the study (Dudovskiy, 2017). The researcher in this study selected the grade 

9 students as it was the first level after the middle school, which is appropriate for the study, 

and they became the next group who conducted the NAT. It is also because, during mid-

school classes, there is a rise in an imbalance of mathematics teaching (Sun, 2015). 

In selecting the two groups, the students’ previous mathematics grades were examined to 

ensure no significant difference between the student’s initial performances in mathematics 

and were comparable. The implementation group and comparison group were established 

through a toss coin. Each class comprised of 30 students, 17 male and 13 female in the 

implementation group, and eight male and 22 female in the comparison group. The 

researchers have explained the respondents that they were purposively selected, and informed 

consent was secured. They also discussed the role of the respondents and other ethical details. 

Moreover, the confidentiality of respondents’ scores in the procedural test, mindset 

questionnaire, and other responses was assured. 

 

Research Procedure 

A letter of asking permission to conduct the study was created and proposed to the 

Department of Education’s Schools Division Superintendent and the school supervisors for 

approval. The researchers began preparing, developing, and validating the data collection 

instruments after receiving the approval. The group of students in    (implementation) and 

   (comparison) was provided a pre-test and post-test in 30-item researcher-made test in 

mathematics to identify their procedural fluency. Before the intervention, a pre-test (O1) was 

administered to the group, then a post-test (O2) was conducted after the intervention. The 

difference between the pre-test and post-test (Q1 - Q2) was employed to ascertain whether 

there is a change or gain due to supplementary materials of integrating growth mindset 

principles (intervention, X). 

Quantitative data encompasses students’ responses to the mindset questionnaire and 

feedback on their journals, and informal interviews regarding their experiences during the 

supplementary materials implementation. The students’ mindset scores from the mathematics 

interview schedule questionnaire were investigated by utilising a quantitative method. 

Furthermore, journal and informal interviews were administered to demonstrate the 

improvement of a growth mindset among students in applying the supplementary materials. 

The data gathered were then accommodated and organised for presentations and analysis. 

The researchers prepared the research report after the data were arranged, analysed, and 

interpreted. 

 

Research Tool and Analysis 

The study utilised the adopted validation guide from the DepEd as the instructional 

materials evaluation tool in validating the developed supplementary materials along with 

their features (DepEd Naga City Division Order No. 441, series of 2019). The researcher 

demanded the panel of experts to portray their opinion on the statements and item regarding 

the features of the supplementary materials by incorporating comments and suggestions for 

improvement.  



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

16 

 

The instructional material evaluation tool possesses a five-point scale with the following 

descriptive interpretation: 4.51-5.00 (outstanding), 3.51-4.50 (very satisfactory), 2.51-3.50 

(moderately satisfactory), 1.51-2.50 (poorly satisfactory), and 1.00-1.50 (not satisfactory). 

The supplementary materials were assessed in three components in particular: mathematics 

content, features, and technical aspects.  

Along with the mathematics content, the supplementary materials were examined 

concerning the consistency to learning competencies, objectives and accuracy of the content. 

Along with the features, the evaluation process concentrated on the supplementary materials’ 

features and appropriateness to the objectives as reflective learning activities, motivational 

activities, and instructional videos. Finally, along with technical aspects, the supplementary 

materials were evaluated in regarding the application of stimulating graphics, utilising 

colours pleasing to the eye, readability, and organisation of texts, consistency in the 

utilisation of font, colours, and design, presentation of the cover page, and the easiness to 

reproduce.  

 The validated procedural fluency test was employed for pre-test and post-test in 

identifying students’ procedural fluency. It incorporates the lessons established for the 4
th

 

quarter of the SY 2020-2021 based on the Most Essential Learning Competencies (MELCs) 

under the K-12 Curriculum of the DepEd. The procedural fluency test was designed with a 

table of specifications to ensure that the test items were equally distributed among the topics 

and learning competencies encompassed in the test.  

The researcher implemented the mindset questionnaire of Dweck (2006) during interview 

schedules to collect students’ pre- and post-scores in mindset in mathematics. The 

questionnaire comprises 20 statements illustrating growth or fixed mindset (questions 

directed to mathematics performance). The respondents responded with the scales of strongly 

agreed, agreed, disagreed, or strongly disagreed with the statement. The statements were 

assigned point values. If the statement was a fixed mindset statement, the point values were: 

0 points for strongly agree, 1 point for agree, 2 points for disagree, and 3 points for strongly 

disagree. If the statement demonstrated a growth mindset, the point values were: 3 points for 

Strongly Agree, 2 points for agree, 1 point for disagree, and 0 points for strongly disagree. 

The interpretation of the total mindset scores comprises 00-20 (strong fixed mindset), 21-33 

(fixed mindset with some growth ideas), 34-44 (growth mindset with some fixed ideas), and 

45-60 (strong growth mindset).  

The fixed mindset statements encompass, “Some people are good in mathematics and kind 

(patience in mathematics), and some are not – it is not frequently that people change”. 

Meanwhile, the growth mindset statements incorporated a statement like “all human beings 

are capable of learning mathematics”. For instance, supposing a student’s mindset survey 

score declines between 00-20. In that case, he possesses a strong fixed mindset which implies 

his belief that mathematics ability is fixed and cannot be learned through effort, as he 

responded to the questions in the mindset survey. Furthermore, if a survey score of students’ 

mindsets descends between 21-33, he owns fixed ideas about mathematics ability but also 

believes in any other method that mathematics can be learned through exercise, as he 

responded to the mindset questions.  

Unstructured interview, focus group discussion questionnaires, journals, and outputs were 

also considered to corroborate the findings of the study through thematic analysis. Frequency 



Christian R. Repuya & Jedh Esterninos  

                    
17 

  

count was employed to calculate the number of occurrences of respondents’ answers under 

the different questions and the number of students’ correct responses in the mathematics 

researcher-made pre-test and post-test in procedural fluency. Moreover, it also administered 

to measure the number of students’ growth mindsets based on the scale and interpretation.  

The difference between the pre-test and post-test of the students on the procedural fluency 

exam was determining the application of the Mean Difference/Mean Gain method. The 

students’ procedural fluency and performance levels were identified by utilising the 

percentage technique. According to the National Council of Teachers of Mathematics 

(NCTM) (2014), the ability to implement procedures precisely, efficiently, and flexibly; to 

transfer procedures to new issues and contexts; to generate and adjust procedures from other 

procedures, and to comprehend the moment of one technique or method is more appropriate 

to implement than the other is procedural fluency.  

In this study, students’ performance level in procedural fluency concerns on the student's 

scores on a 60-item procedural fluency multiple-choice test formulated and validated by the 

teacher, and answered by students in the pre-test and post-test. The performance level of the 

students was interpreted by administering the scale: 35 and below (very low mastery), 36-65 

(low mastery), 66-85 (average mastery), 86-95 (moving towards mastery), and 96-100 

(mastered). 

 

Results and Discussion 

The primary concern of this study is to enhance supplementary materials for ninth-grade 

mathematics with growth mindset principles integration which was expected to help students 

encourage and enjoy learning and possess meaningful learning while studying at home. The 

study’s outcomes could serve as supplemental materials to corroborate mathematics teachers 

in teaching mathematics to enhance students’ procedural fluency and mindset in mathematics.  

The developed supplementary materials encompassed six lessons for ninth-grade 

mathematics, such as the six trigonometric ratios, the trigonometric ratios of special angles, 

angles of elevation and angles of depression, trigonometric ratios to solve real-life problems 

incorporating right triangles, laws of sines and cosines, and problems accommodating oblique 

triangles. Each lesson was anchored to the most essential learning competencies of the Ninth-

Grade Mathematics Curriculum and adhered the policy on lesson planning of the Department 

of Education.  

Five jurors subjected the developed supplementary materials to critiquing. 

The jurors provided their comments, suggestions, and recommendations to enhance each part 

of the lessons and supplementary materials. The developed lessons possess specific features 

in which the developed supplementary materials incorporate growth mindsets. These are 

motivational activities, reflective learning activities, and integration instructional videos to 

assist students enhance a strong growth mindset in mathematics. 

 

Motivational Activities 

Table 1 presents the integration matrix of the growth mindset principle through 

motivational activities in the developed supplemental materials for teaching ninth-grade 

mathematics. Motivational activities in every lesson were employed to make students more 



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

18 

 

prepared. Each topic was associated with them, leading them to think about the growth 

mindset principles.  

For instance, in lesson 1, along with the “Let’s start”, the students read the direction and 

employed the words in the box to complete the sentence. It came up with the phrases “I will 

do my best”, “I can perform more effort”, “I can learn from my mistakes”, “I can achieve my 

goals”, and “I can overcome challenges”. These phrases are concerning about the growth 

mindset that the students require to enhanced. According to Dweck (2006), if the students 

think that their success is based on hard work, learning, and training, individual possesses a 

growth mindset. In this activity, students will identify what they require to remember to more 

succeed the learning on particularly topic. In that case, the student can improve their growth 

mindset.  

In lesson 2, along with the “Let’s start” part, the activity assisted the students develop their 

growth mindset in a method that they require to realise that for them to enhance their 

performance, they need to learn new things, welcome constructive feedback, discover 

creative solutions to solve a problem, elevate with practice, and train their brain. The 

activities in lessons 3 and 4, “Discovering a Solution to a Problem” and “Converting 

Negative to Positive”, may enhance the students’ growth mindset.  

 

Table 1 

Integration of Growth Mindset Principles via Motivational Activities 

Lessons Activities Description 

Lesson 1:  

 

The Six 

Trigonometric 

Ratios: 

Sine, Cosine, 

Tangent, 

Secant, 

Cosecant, and 

Cotangent  

Challenge Yourself to Succeed 

 

Direction: Use the words in the box to fill in the 

blanks 

 

1. I will do my ___________ 
2. I can put in more _______  
3. I can learn from my _____ 

4. I can achieve my _______ 

5. I can overcome ________ 

 

 

This activity was anchored on the 

growth mindset principle. This activity 

allows students to understand that our 

belief about intellectual abilities can 

be enhanced for us to be successful.  

 

In this activity, students have 

discovered what they need to 

remember to be more successful in 

understanding the topic. Hence, the 

students are able to improve their 

growth mindset. 

 

Lesson 2:  

 

The Six 

Trigonometric 

Ratios of 

Special 

Angles 

Improve and Develop 

Direction: Match the appropriate word 

Column A      Column B 

I can learn ______________       a. solutions 

I welcome constructive ____       b. practice 

I can train my ___________        c. new things 

I can improve with _______        d. brain 

I can find creative _______         e. feedback 

This activity assists the students to be 

aware that there are principles that we 

need to follow to enhance our 

performance. The students matched 

the appropriate word from column B 

to complete the sentence to realise 

this. 

 

This part concerns on developing the 

students’ growth mindset that 

knowledge is not fixed but can be 

improved. 

 

 

 

challenges 
goals  

best 

mistakes 

effort 



Christian R. Repuya & Jedh Esterninos  

                    
19 

  

Lessons Activities Description 

Lesson 3:  

 

Angle of 

Elevation and 

Angle of 

Depression 

Finding a Solution to a Problem 

Direction: Match the correct solution to a problem 

from column A to column B 

 

 

 

 

 

 

 

 

 

 

  
The students matched column A to 

column B to get the correct solution to 

a problem or scenario. 

 

 

This activity focuses more on 

developing the students’ growth 

mindset that there is no problem if 

there is no solution.  

 

 

 

 

 

 

Lesson 4:  

 

Solving Word 

Problems 

Involving 

Right 

Triangles 

Negative to Positive 

Direction: Convert the following negative thought 

to positive thinking. 

 

Negative Thoughts Your Positive 

Thoughts 

1. Mathematics is a very 

hard subject for me. 

1. 

2. I cannot solve any 

problems in 

Trigonometry 

concerning right 

triangles. 

2. 

3. I never understand 

the concept and process 

of solving problems in 

Mathematics. 

3. 

4. I think that my 

teacher does not care 

about my learning. 

4. 

5. I could not complete 

high school because 

there was a lot of 

homework and projects. 

5. 

6. I cannot go to college 

because it is very hard. 

6. 

7. I cannot study 

without the help of my 

classmates or my 

friends 

7. 

8. I think that I am not 

good at anything. 

8. 

9. I never do anything to 

succeed. 

9. 

10. I cannot achieve my 

dream and be a 

successful person. 

10. 

 

In this Activity, “Negative to 

Positive”, The students convert the 

following negative thoughts to 

positive thinking. 

 

 

This activity is more on elevating the 

students' growth mindset that for us to 

be successful in life, we require to 

practice converting negative thoughts 

into positive thinking. 

 

The students answered the following 

questions: 

1. How did you convert the following 

negative thoughts to positive 

thoughts? 

 

2. How can this activity assist you to 

be optimistic and motivated to learn? 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

20 

 

Lessons Activities Description 

Lesson 5:  

 

Oblique 

Triangles:  

Sine Law, 

Cosine Law, 

and the 

application 

You Can Do It. Trust Yourself 

Direction: Formulate your own motivational quotes 

that you can always remember to be a successful 

person someday. 

 

Answer the following questions: 

1. How can this motivational quote help you in 

your study about this topic in this module? 

2. What are the things you need to perform now to 

achieve your dreams? 

3. From the quotes you have encountered in the 

previous modules, what quote do you like the 

most? Why and how will you apply those to grow 

and develop as an individual? 

 

In this activity, the students generated 

motivational quotes that they can 

always remember for them to be a 

successful person someday. Hence, it 

helps the students to enhance their 

growth mindset. 

 

 

 

This section is able to develop the students’ growth mindset; hence, they need to realise 

that every problem, big or small, must possess a solution, and failure and mistakes are not 

bad things. The motivational activity in lesson 5 is “You can do it, Trust Yourself”. In this 

activity, the students created motivational quotes that they can always remember to be a 

successful person someday. This section enhances students' growth mindset; thus, the 

students will realise that there is no other way to enhance themselves but by trusting 

themselves.  

Briggs (2015) stated in his article that learning takes time and do not anticipate learning 

everything in one session. It indicates that the students need to exert efforts to learn and 

realize that knowledge is not fixed but can be enhanced. When students make a mistake or 

own a problem, they have not failed but they have learned instead. He recommended 

replacing the word “failing” with “learning” which can improve students’ growth mindset. 

Furthermore, students should stop finding approval from others because when students 

prioritise approval over learning, they sacrifice their growth potential. 

 

Reflective Learning Activities 

Reflective learning was one of the features of the developed supplementary materials 

accommodated on the growth mindset employed in this study. Gray (2021) defined reflective 

learning as students’ thinking about what they have learned in the classroom and how it is 

implemented into their individual life. It is a method of learning in which students reflect 

upon their learning experiences. Reflective learning also allows the students to reflect on their 

learning. 

In this study, reflective learning concerns on the students’ reflections in the lesson format 

which implement supplementary material attached on growth mindset principles and the 

approach employed in the development of the lessons. Table 2 presents the promotion of 

reflective learning, another feature of the developed supplemental materials for teaching 

ninth-grade mathematics.  

 

 

 



Christian R. Repuya & Jedh Esterninos  

                    
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Table 2 

Promoting Reflective Learning 

Lessons Reflective Learning Theme Description 

1 

 

“Success is not an accident. 

Success is a choice”. – 

Stephen Curry (n.d.) 

In this lesson, reflective learning was performed in the “Let’s 

Reflect” part, in which the students reflect on their learning. The 

students reflect on the provided quotation, that is about being 

successful. This activity will motivate the students to study hard 

for the successful outcome. 

 

2 “Learn everything you can, 

learn anytime you can from 

anyone you can – there will 

always come a time when you 

will be grateful for what you 

did” – Sarah Caldwell (n.d.) 

 

The quotation about learning by Sarah Caldwell was employed to 

promote reflective learning. 

In the “Let's reflect” part, the students reflect on their learning and 

the provided quotation about the importance of learning.  

The students will realise that learning is essential.  

It also helps to improve the growth mindset of the students. 

3 “Work to find solutions 

instead of always highlighting 

the problems”. 

– pictureqoutes.com (n.d.) 

The promotion of reflective learning in this lesson is on the “Let’s 

reflect” part, in which the students reflect on the quotation about 

discovering a solution for a problem. 

It will also assist the students to enhance their problem-solving 

skills, accommodated to the growth mindset principles. 

 

4 “Once you replace negative 

thoughts with positive ones, 

you will start having positive 

results” – Willie Nelson (n.d.) 

In this lesson, reflective learning was introduced in the “Let’s 

Reflect” part, in which the students reflect on their learning. The 

students also reflect on the provided quotation, which is about 

being positive. This activity will encourage students to study hard 

and avoid any negative thoughts. 

 

5 

 

“Trust yourself. You know 

more than you think you do”. 

– Benjamin Spock 

The quotation about trusting oneself by Benjamin Spock was 

administered to promote reflective learning. 

In the “Let's reflect” part, the students reflect on their learning and 

the provided quotation about the importance of self-confidence.  

The students will realise that trusting oneself is crucial in learning 

and achieving goals.  

In the “Let’s Reflect” part, the last part of every developed lesson, the students reflect on 

the provided quotations. For instance, in lesson 1, the quotation is about success by Curry 

(n.d) “Success is not an accident, success is a choice”. The student reflected on this quote to 

encourage them to study hard for being successful. This part also allows the students to 

review and reflect on their learning and new understanding.  

In this part, the students were also asked about what they have learned, the difficulties they 

experienced, what they learned from these quotes at each start of the lesson, and the way to 

apply the things they have learned to acquire their goals. As another part of their reflections, 

they were also asked to write their significant learning experiences to capture their significant 

learning experience during the conduct of the study.  

Elias (2010) explained that students’ reflections were identified as one of the top six 

activities to assist students to be successful. He asserted that students should formulate their 

goals, record the achievements, and show and share the learning with others. 

Promoting reflective learning in lesson 2 was on the “Let's Reflect” part. The students 

reflected on the quote by Caldwell (n.d), which is “Learn everything you can, learn anytime 

you can, learn from anyone you can – there will always come a time when you will be 

grateful for what you did”. In this activity, the students realised that learning was essential 

and help them enhance their growth mindset.  



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

22 

 

Malec (2021) elaborated that continuous learning is vital because it assists students feel 

joy in life and elevate their productivity. When students realise the importance of learning, 

they will be encouraged and eager to learn. The students also reflected on what they did and 

learned from activity two and how it helped them prepare for the topic. The difficulties they 

have encountered in the lesson and how they solved it, how the concepts they have learned 

are applied in real life, and how it may assist them to achieve their goals. 

The theme in lesson 3 was “finding a solution to a problem”. Problems in learning are 

frequently present, hence, the students sometimes do not understand what to perform. In this 

part of the promotion of reflective learning, the students reflected on the quotation about 

finding a solution to a problem: “Work to find solutions instead of always highlighting the 

problems” (pictureqoutes.com). It helps the students improve their problem-solving skills and 

promote growth mindset principles. 

In lessons 4 and 5, the students reflected on the quotations about possessing positive 

thoughts and trusting themselves. One of methods for them to succeed is to be positive and 

trust themselves. As cited by Williams (2017), Dewey asserted that reflection was a 

tremendous significant part of learning. He advocates that reflective learning is not merely 

reading and obtaining knowledge. It is an active examination of learning from 

the information in accordance with the students’ learning experiences. The students need to 

think deeply based on what they have read and learned from the lesson. Then, they can 

implement the knowledge to their context. The implementation of supplementary material 

with its features makes learning meaningful to the students since they can reflect and freely 

express their selves about what they have studied. It also encourages learning transfer 

because students would easily identify the concepts as they reflect on their personal 

experiences. 

Furthermore, the DepEd promoted reflective learning in the K to 12 Basic Education to 

provide a meaningful learning experience. Reflective learning allows learners to employ what 

they have learned and why they need to learn (Department of Education Order No. 21, series 

of 2019). Additionally, Briggs (2015) stated that if the students are allowed to reflect on their 

understanding at least regularly, they can enhance their growth mindset. Opportunities for 

reflection encourage the students to be motivated to learn and elevate their interest in 

learning. 

Integration of Instructional Videos 

Integrating instructional videos was one of the features of the developed supplementary 

materials encompassed on the growth mindset employed in this study. Any video displaying a 

procedure, transmitting knowledge, explaining a concept, or presenting someone how to 

accomplish something are classified as an instructional video. It means that it is a form of 

instruction utilising technology to convey knowledge to the viewers (Simon, 2012). 

According to Mendoza et al. (2015), employing instructional materials and integrating 

instructional video obtains the student's interest. It also helps the students to concern on the 

lessons. 

Table 3 presents the developed supplemental materials featuring the integration 

instructional video teaching ninth-grade mathematics. Videos in each lesson were utilised as 

instructions that assisted students to comprehend each topic in mathematics and were 



Christian R. Repuya & Jedh Esterninos  

                    
23 

  

associated with them, improving their understanding and interest in mathematics.  

In this study in lesson 1, the instructional video is all about the concept of the six 

trigonometric ratios, portraying the parts of a right triangle and illustrating the six 

trigonometric ratios. It also displays the method to identify the missing parts of the triangle 

and its application in real life. In lesson 2, the instructional video discusses about the 

“trigonometric ratios of special angles”. The students watched the video which portrays the 

concept of Trigonometric Ratios of Special Angles, discovering the missing parts of the 

tringle utilising special angles, and its application in real life. After watching the instructional 

video, they were writing what they had learned in their notebook and answered some 

questions associated with the discussion.  

 

Table 3 

Integrating Instructional Videos  

Lessons 
Instructional 

Videos 
Descriptions 

Lesson 1:  

 

The Six 

Trigonometr

ic Ratios: 

Sine, Cosine, 

Tangent, 

Secant, 

Cosecant, 

and 

Cotangent  

“The Parts of the 

Right Triangle” 

 

 

 

 

 

 

“The Six 

Trigonometric 

Ratios” 

 

 

“Trigonometry – 

Application” 

This instructional video in this section integrated into the “Let’s Start” 

part, activity number 2, in which the students watched the video 

segment to assist them to recall the different concepts about a triangle 

and answered the following questions: 

1. What are the parts of the right triangle? 

2. What are the definitions of the parts of a right triangle? 

3. Is it easy to identify the parts of a right triangle? Why? or why not? 

 

Another instructional video in this section also accommodated “Let’s 

find out” part, and they wrote the things they had learned from the 

video. The concepts of The Six Trigonometric ratios were further 

discussed. 

 

In the “Let’s apply” part, the students watched the instructional video 

and solve the provided worded problem about the six trigonometric 

ratios and answered the following questions: 

1. Did you obtain the correct answer? How?  

2. Is the problem easy to solve? Write the difficulties you've 

encountered if you have one?  

3. If you were asked to make your trigonometric ratio problem, how 

would you make it? 

Lesson 2:  

 

The Six 

Trigonometr

ic Ratios of 

Special 

Angles 

“Exact 

Trigonometric 

Ratios by 

Employing Your 

Hands”. 

 

 

 

 

 

“Trigonometric 

Ratios of Special 

Angles” 

 

 

“Trigonometry – 

Application” 

The instructional video in the “Let’s Start” part was on activity 

number 2. The students watched the video segment to help them 

remember the exact trigonometric values employing their hands. 

Then, they answered the following questions: 

1. How did you feel after you watched the video? 

2. Did employing the hand trick in finding exact trigonometric values 

make you easily compute the values of trigonometric ratio? 

3. How could you utilise the trigonometric ratios hand trick in finding 

the unknown angles or sides of a special right triangle? 

  

In the “Let’s find out” part, the instructional video in this part talks 

about the concept of Trigonometric Ratios of Special Angles. The 

students watched the video, and they wrote the things that they had 

learned. 

 

Another instructional video incorporates on “Let’s apply” part. The 

students watched the video about solving problems involving 

trigonometric ratios of special angles and solve the provided worded 

problems. 



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

24 

 

Lessons 
Instructional 

Videos 
Descriptions 

Lesson 3:  

 

Angle of 

Elevation 

and Angle of 

Depression 

“Angle of 

Elevation and 

Angle of 

Depression” 

 

 

 

 

 

 

 

 

 

Clinometer (How 

to make and use) 

The instructional video in this lesson was on the “Let’s find out” part, 

and it discussed about the concept of the Angle of Elevation and the 

angle of depression. This content discussed all the content. 

The students watched the video segment and wrote what they had 

learned. 

 

Questions: 

1. Based on the video you’ve watched, what is the definition of angle 

of elevation? 

2. What is angle depression? 

3. What are the differences between the angle of elevation and 

depression? 

 

The instructional video in this part was the video containing the way 

to create a clinometer. The students followed the steps in making a 

clinometer based on the instructions from the video, and then the 

students performed activity 4. 

 

In Activity 4, “Your Shadow”, students calculate the height of their 

friend and the length of his/her shadow. Applying the concept of 

trigonometric ratios, the students determined the angle of elevation 

from the ground to the sun. 

Lesson 4:  

 

Solving 

Word 

Problems 

Involving 

Right 

Triangles 

“The Scientific 

Calculator” and 

“Example 

Problem” 

The instructional video in this lesson was about utilising the scientific 

calculator and solving problems incorporating the right triangle. The 

students watched the video segment about the example of problems 

involving right triangles applying the trigonometric ratios and wrote 

what they had learned.  

Lesson 5:  

 

Oblique 

Triangles:  

Sine Law, 

Cosine Law, 

and its 

application 

“Sine and Cosine 

Law: Finding the 

missing parts of an 

oblique triangle”. 

 

 

“Sine and Cosine 

Law – 

Application” 

The instructional video in this lesson was all about oblique triangles. 

The students watched the video segment entitled “Oblique Triangles” 

Sins and Cosine Law: Finding the missing part of an Oblique 

Triangle, and afterward, they wrote the things they had learned. From 

the video, the concepts were further discussed. 

 

Another video on this part discussed about the application of Sine 

Law and Cosine Law. The students watched the video about Sine Law 

and Cosine Law–Applications and solved the provided worded 

problems. 

 

There is an instructional video in activity 2, in which the students were watching the video 

segment entitled “trigonometric ratios shortcuts” to assist them remember the exact 

trigonometric values by employing their hands. The short video presents the way to memorise 

exact trigonometric values by employing the hand trick. The video helps the students easily 

compute trigonometric ratios’ values, and employ the trigonometric ratios hand trick in 

identifying the unknown angles or sides of a special right triangle. There is also a video about 

the implementation and how to solve problems regarding trigonometric ratios of special 

angles. This video displays the students how to solve problems involving trigonometric ratios 

of special angles.  

In lesson 3, the instructional video in this lesson is on the “Let’s find out” part. It discusses 

about the “angle of elevation and angle of depression”. The students were watching the video 

segment about the “angle of elevation and angle of depression”. The video displays the way 

the angle of elevation and angle of depression is employed in solving word problems 



Christian R. Repuya & Jedh Esterninos  

                    
25 

  

incorporating right triangles and application in real life. They were also writing about what 

they had learned from the video for their reflection and evaluation purposes. There is also a 

video about how to make a clinometer. The video teaches the students on how to make and 

utilise the clinometer to calculate the angle of objects.  

After they have watched the video, an activity follows, which is activity 4. In Activity 4, 

entitled “Your Shadow”, students measured the height of their friend and the length of his/her 

shadow. Employing the concept of trigonometric ratios, the students examined the angle of 

elevation from the ground to the sun. Employing the clinometer, they could calculate the 

angles. After the activity, there are also questions that they require to answer as a part of the 

evaluation, 

In lesson 4, the instructional video is on the “Let’s find out” part. It is all about solving 

problems encompassing the right triangle, utilising the scientific calculator, and employing 

concepts in the previous lesson to solve problems incorporating the right triangle. The 

students watched the video segment about example problems concerning right triangles 

utilising the trigonometric ratios. 

In lesson 5, the instructional video is on the “Let’s find out” part. It was about oblique 

triangles. The students watched the video segment entitled “Oblique Triangles” sins and 

cosine law: discovering the missing part of an oblique triangle. There was also a video on the 

“Let’s apply” part. The video on this part discussed about implementing sine and cosine law. 

The students watched this video and solved the provided worded problems.  

There are six lessons developed with instructional videos, that are the six trigonometric 

ratios, the six trigonometric ratios of special angles, the angle of elevation and angle of 

depression, solving word problems incorporating right triangles, and oblique triangles: sine 

law, cosine law, and its application. 

 

Effects on the Students’ Procedural Fluency in Mathematics  

Procedural fluency is the ability to implement procedures accurately, efficiently, and 

flexibly, to correlate procedures to different problems and contexts, build and modify 

procedures from the other ones, and recognise when one strategy or procedure is more 

appropriate. In developing procedural fluency, students should experience rationalising both 

informal approaches and general employed procedures mathematically, should establish and 

defend their choices of appropriate procedures and reinforce their knowledge and skills 

through the distributed practice (NCTM, 2014).  

Employing supplementary materials anchored on growth mindset principles in the 

development of the lessons in ninth-grade mathematics allows students to enhance procedural 

fluency. Table 4 presents the pre-test and post-test results provided for students in the 

implementation group. It indicates that the mean scores of the students in the implementation 

group during the pre-test were all interpreted as very low mastery except for the fourth 

competency on solving real-life problems which encompass right triangles classified as low 

mastery.  

 

 

 

 



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

26 

 

Table 4 

Result of Pre-test and Post-test in the Procedural Fluency 
 Implementation Group Comparison Group 

Topics No. of 

Items 

Pre-test Post-test Mean 

Gain 

Pre-test Post-test Mean 

Gain Mean 

 

Interpret

ation 
Mean 

 

Interpret

ation 
Mean Interpret

ation 
Mean 

 

Interpret

ation 

The six 

trigonometric 

ratios 
4 

0.97 

(24.3%) 
VLM 

3.1 

(77.5%) 
AM 2.13 

1.2 

(30%) 

VL

M 

2.2 

(55%) 
LM 1 

Trigonometric 

ratios of special 

triangles 
4 

0.93 

(23.3%) 
VLM 

1.9 

(47.5%) 

 

LM 
1.27 

1.1 

(27.5%) 

VL

M 

1.5 

(37.5%) 
LM 0.4 

Angles of 

elevation and 

depression 
7 

 

1.37 

(19.6%) 

 

VL

M 

 

3.7 

(52.9%) 

 

LM 
2.33 

 

2.6 

(37.1%) 

LM 

 

3.1 

(44.3%) 

LM 0.5 

Solving real-life 

problems 

involving right 

triangles 

3 

 

1.4 

(46.67%) 

LM 

 

2.3 

(76.7%) 

 

AM 
0.9 

 

1.4 

(46.7%) 

LM 

 

1.9 

(63.3%) 

LM 0.5 

The laws of sines 

and cosines. 9 
2.37 

(26.3%) 
VLM 

4.6 

(51.1%) 
LM 2.23 

3.5 

(38.9%) 
LM 

4 

(44.4%) 
LM 0.5 

Solving problems 

involving an 

oblique triangle 
3 

0.6 

(20%) 

 

 

VLM 

1.4 

(46.7%) 
LM 0.8 

0.8 

(26.7%) 

 

VL

M 

1.2 

(40%) 
LM 0.4 

Total 30 
7.63 

(25.5%) 
VLM 

16.87 

(56.2%) 
LM 9.24 

10.67 

(35.6%) 

VL

M 

13.93 

(46.4%) 
LM 3.23 

Legend: VLM – Very low Mastery, LM – Low Mastery, AM – Average Mastery, HM – High Mastery, VHM – Very high 

mastery, p* tested at a .05 level of significance 

 

Looking at the data, the learning competency “solving real-life problems involving right 

triangles” (46.67%) owned the highest performance level, while the lowest was on “illustrates 

angles of elevation and angles of depression” (19.6%). During the post-test, the students 

acquire the highest performance level on “The six trigonometric ratios” (77.5%), while the 

lowest performance was on “Solving problems involving oblique triangle” (46.7%).  

Overall, the total mean score for the pre-test was 7.66 (25.5%), interpreted as very low 

mastery, and 16.87 (56.2%), construed as a low mastery for the post-test, which displayed an 

increase of 9.24. Results presented a difference in the students' performance in the group 

from pre-test to post-test. The table revealed an increase in the mean of post-test of 3.1, 1.9, 

3.7, 2.3, 4.6, and 1.4 on competencies 1 to 6, respectively. It indicates that the students in the 

implementation group who employed the instructional materials enhanced the students’ 

procedural fluency in terms of the lessons incorporated in the study. With the result, it is 

implied that the students who were taught utilising the supplemental materials obtained a 

high mean score in the post-test since there was an increase in the mean score of the pre-test.  

The possible reason for this accomplishment and improvement in performance level may 

be attributed to the supplemental materials, which enable students to comprehend well and 

exert effort in learning. One of the students expressed her thoughts about learning with the 

materials which is the way she applied what she has learnt and the way to achieve the goal.  

 

 



Christian R. Repuya & Jedh Esterninos  

                    
27 

  

The students explained: 

Student 3: “In achieving our goal, we require to possess hardship or work through step 

by step, hence, it will be easy for us to perform such things”. 

 

Student 7: “I have some difficulties in finding the best way to solve the problem, 

particularly of which trigonometric ratios will be utilised. However, by trying to 

understand the problem, again and again, I can solve the problem”. 

 

Based on the student’s entry, they learned to solve trigonometric ratios based on their 

growth mindset. Even though solving worded problems was complicated, they attempted 

their best to discover the right answer. The student explained that learning step by step to 

solve the problem was significant for her to better understand the problem and to succeed 

identifying solutions. 
In conclusion, the lessons and activities in the supplementary material significantly 

enhanced the students’ procedural fluency. The data collected corroborated the students’ 

reflection, and it revealed that employing activities (such as studying with the instructional 

videos that allow them to think, reflect and correlate their lives to the lessons) enables the 

students to understand the mathematics concepts better. Moreover, the students manifested a 

growth mindset in mathematics, leading them to strive and learn the topics more.  

Table 4 portrays that the mean scores of the students in the comparison group during the 

pre-test were interpreted as low mastery of “angles of elevation and depression”, “Solving 

real-life problems involving right triangles”, and "the laws of sines and cosines, and very low 

mastery for “the six trigonometric ratios”, “trigonometric ratios of special triangles” and 

“solving problems involving oblique triangle”. Observing the data, the learning competency 

“solving real-life problems involving right triangles” (46.7%) possessed the highest 

performance level while the lowest was on “Solving problems involving oblique triangle” 

(26.7%). 
Based on the same table, in the post-test of the comparison group, the students acquired 

the highest performance level on “real-life solving problems involving right triangles” 

(63.3%), while the lowest performance was on “trigonometric ratios of special triangles” 

(37.5%). Data also unveiled that the students owned low mastery of all six competencies. 

Overall, the total mean score for the pre-test was 10.67 (35.6%), construed as very low 

mastery, and 13.93 (46.4%), also portrayed as a low mastery for the post-test. Based on the 

table, it could be inferred that the utilisation of the traditional method of teaching and 

reference materials also enhanced the students’ procedural fluency in terms of the lessons 

encompassed in the study, with the mean scores of 10.67 and 13.93 in the pre-test and post-

test, respectively, which displayed an increase of 3.23.  

The implementation group possesses a higher increase with an increase of 9.24 for the 

implementation group than the comparison group with an increase of 3.23. A t-test for an 

independent sample was administered to determine if there was a significant difference in the 

mean gain scores of the students between the implementation and comparison groups in 

procedural fluency. The results revealed a significant difference between the mean gain 

scores of the two groups, conveyed by the t-value of 4.890 and p-value of 0.000, which was 

significant at a 95% confidence level. 



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

28 

 

Comparing the increase of the mean score of the implementation group to the comparison 

group, the implementation group owns a higher increment with an increase of 9.24 for the 

implementation group compared to the comparison group with an increase of 3.23. The study 

uncovered that the students in the implementation group taught by applying the 

supplementary materials enhanced procedural fluency in mathematics more than those in the 

comparison group. The latter was taught by the traditional method and did not employ 

supplementary materials.  

Bautista (2013), in his study, revealed that to remodel students’ performance on 

procedural fluency and mathematical explanation toward problem-solving, the instructional 

activities, mindset, and contents have to be complementary to one another. Furthermore, the 

study by Arthur, Dogbe, and Asiedo-Addo (2021) discovered that motivation in learning 

mathematics and quality of mathematics teaching obtained significant positive effects on 

students’ mathematics performance.  

In the present study, the improvement in the implementation group could be attributed to 

the student's application of the supplementary materials in which they are able to learn the 

materials at home. The contribution of the study in elevating the students’ procedural fluency 

were administering the motivational activity with a growth mindset that helps the students be 

motivated to learn and possess a high interest in learning the topics in mathematics. 

Reflective learning activities provide a clear goal for attaining the learning objectives in 

which students are encouraged to perform reflection activities. The instructional videos help 

students learn and comprehend more of the concept at home and be able to employ 

technology such as phones and computers as an additional tool for researching instructional 

resources.  

The study by Sharma (2018) discovered that students receiving steady experience to 

instructional videos and real-life activities performed better than students receiving some of 

the exclusive instructional treatments. The students, during the interviews, manifested their 

belief that instructional videos and real-life activities were able to enhance their 

understanding on mathematical concepts. 

 

Effects on the Students’ Mindset in Mathematics 

The effects of the motivational activities on students’ mindsets were also the 

manifestations of the development of a growth mindset among students in performing the 

activity. Dweck’s (2006) mindset questionnaire was administered to calculate it by utilising 

an interview schedule. Students answered with a growth mindset or a fixed mindset for each 

statement. A student with a growth mindset and some fixed ideas experienced that his or her 

mathematical skill could be improved, but he or she also believed that some aspects of his or 

her mathematical skills could not be modified. 

A student with a fixed mindset, on the other hand, acknowledged that his or her 

mathematical skills could not be changed or elevated; nevertheless, he or she might believe 

that it could be enhanced in certain ways. The data was analysed through frequency count 

after determining the students’ mindsets. Table 5 presents the summary of the pre-test and 

post-test frequency counts of the students’ mindsets in the implementation group and 

comparison group.  



Christian R. Repuya & Jedh Esterninos  

                    
29 

  

In the implementation group, 17 students owned a “fixed mindset with some growth 

ideas”, while 13 possessed a “growth mindset with some fixed ideas”. 13 students owned a 

fixed mindset with some growth ideas during the post-test, 14 students possessed a growth 

mindset with some fixed ideas, and three students owned a strong growth mindset. 

 

Table 5 

Summary of the Pre-test and Post-test Frequency Counts of Two Groups on Growth Mindset 

in Mathematics 

Mindsets of the students in 

Mathematics 

Pre-test Post-test 

Implementation 

Group 

Comparison 

Group 

Implementation 

Group 
Comparison Group 

Fixed mindset 0 0 0 0 

The fixed mindset with 

some growth ideas 17 10 13 9 

Growth mindset with some 

fixed ideas 13 19 14 19 

Strong growth mindset 0 1 3 2 

Total 30 30 30 30 

      

While 19 students in the comparison group possessed a growth mindset with some fixed 

ideas, ten students owned a fixed mindset with some growth ideas, and one student possessed 

a strong growth mindset during the pre-test. Nine students acquired a fixed mindset with 

some growth ideas during the post-test, 19 students obtained a growth mindset with some 

fixed ideas, and two students gained a strong growth mindset. 

Based on the results, the implementation and comparison groups had students in the pre-

test with a “fixed mindset with some growth ideas”. The students in the implementation 

group all exhibited a growth mindset in the post-test, with no students possessing a robust 

fixed mindset. However, the post-test presented that one student was moved from the 

students with a “fixed mindset with some growth ideas” to the students with a “growth 

mindset with some fixed ideas”, and nothing was added to the students with a “growth 

mindset with some fixed ideas”, elevating the strong growth mindset from one (1) to two (2).  

Specifically, during the post-test in the implementation group, three students from growth 

mindset with some fixed ideas were involved to the students with a strong growth mindset, 

and four students from fixed mindset with some growth ideas were joined into a growth 

mindset with some fixed ideas. Meanwhile, the one student in the comparison who was 

transferred to possess a growth mindset with fixed ideas in the post-test obtained a fixed 

mindset with some growth ideas in the pre-test. Furthermore, one from a growth mindset with 

fixed ideas was switched to strong growth mindset. 

During the post-test in the implementation group, the three students who leaped to 

students with a strong growth mindset enhanced more than the other students. The other 

students have also developed their growth mindset, although just a little. Based on the 

findings, students in the implementation group cultivated a stronger growth mindset than 

students in the comparison group.  

 

 



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

30 

 

The students in the implementation group acknowledge the significance of a growth 

mindset in their education. During the interview, a student (Student 21) moving from a 

growth mindset with some fixed ideas to a strong growth mindset stated the following: 

 

“Nakatabang po talaga sya (motivational activities) sako kasi, sa kada lesson, ugwa 

pong inspiring quotes na nagmomotivate samo, pati si mga activities about motivation 

nakatabang sya na marealize me na kaipuhan ming mag adal para makatapos saka 

makagraduate” (The motivational activities tremendously assisted me a lot because in 

every lesson, there are quotes which encourage us to possess a growth mindset, and the 

activities about motivation help us realise that it is crucial for us to learn diligently to 

accomplish our study, to graduate).  

 

Students’ development of a growth mindset might be associated with utilising 

supplemental materials, which enhances a growth mindset through self-learning that 

emphasises efforts in learning mathematics, in accordance with the students’ statements, as 

previously outlined in their learning experiences. Sun (2019) argued that current school 

mechanisms, such as tracking regulations, instructional methodologies, and standardised 

assessment, may postpone teaching which consistently initiates growth mindset messages 

concerning mathematics ability. It indicates that supplementary materials which utilise 

activities to promote a growth mindset in mathematics could help the students develop a 

growth mindset despite different external factors that convey fixed mindsets. 

The supplementary materials were formulated to enhance students’ growth mindset in 

mathematics, as the motivational activities with the integration of the principles of growth 

mindset are able to make students more engaged in the learning process. Harackiewicz et al.  

(2018) emphasised that interest is a robust motivational mean which elevates learning and is 

essential for the educational success. When students develop their interest in studying 

mathematics due to the motivation, their desire to learn escalates. It implies that teachers 

should determine both considerations in enhancing students’ interest and growth mindset in 

their instruction. 

Boaler (2013) explained that through instructional and classroom activities, teachers and 

institutions regularly transfer messages to students regarding their skill and comprehension 

(i.e., instructional materials). She emphasised that a thorough review of all areas of education 

is required if one is genuinely committed to the transfer and training of a growth mindset. She 

added that, norm-setting, questioning, committing mistakes, providing activities, grouping, 

grading, and feedbacking were all employed to convey mindset messages. 

Briggs (2015) asserted that a growth mindset can alter goals and perceptions of 

achievement. He emphasised that conducting growth mindset-related actions such as 

employing the word “yet”, learning from others’ failures, setting new goals for each goal 

achieved, taking opportunities in the company of others, and thinking realistically about time 

and effort can eventually help students enhance the growth mindset. 

The students were demanded to share their experiences by writing them in their journals to 

corroborate the study’s findings with the actual manifestations of the development of a 

growth mindset among the students in performing the activities. The students’ responses in 

the informal interviews and focus group discussions were also sources to examine the 

manifestations of the development of a growth mindset among the students.  



Christian R. Repuya & Jedh Esterninos  

                    
31 

  

After thematic analysis of the unstructured interviews responses, focus group discussion 

notes, and journals entries of the student during the implementation and after the utilisation of 

the supplemental materials, five themes were generated (Table 6): The students (1) 

acknowledging and embracing imperfections, (2) viewing challenges as opportunities, (3) 

replacing the word “failing” with the word “learning”, (4) providing regular opportunities for 

reflection, and (5) thinking realistically about time and effort. Sample statements of the 

students in each theme were presented in the matrix in Table 6. 

The students’ statements imply that the students developed their growth mindset by 

acknowledging and embracing imperfections. The students accepted that the activities were 

difficult, but it manifested that they possessed a growth mindset due to their 

acknowledgement of imperfections. Another manifestation of the development of a growth 

mindset was the student’s response during the interview, which was by replacing the word 

“failing” with the word “learning”, and the students learned to perform their best even when 

they committed mistakes. It may be attributed to one of the elevated supplementary materials, 

reflective learning activities, which allow the students to reflect on their learning. It is a 

method of learning in which the students are able to reflect upon their learning encounters.  

Based on the students’ reflection, they acknowledged that through the effort, he could 

learn to solve problems. According to Le Cunff (2022), another thing about enhancing a 

growth mindset is situating growth before speed. She asserted that fast learning does not 

necessarily mean equate to good education and learning well requires an investment of time. 

It means that students should also think about the importance of time and effort in acquiring 

new skills. Based on the student’s response, it was identified that the student understands that 

it takes time to grow and improve.  

 

Table 6 

Sample Statements of the Students in Each Theme 

 Themes Description 

 

1 

 

Acknowledge and embrace 

imperfections 

“Today, I experienced that those activities are not easy to resolve, 

but if we perceive all things positively, we can achieve our goals”. 

 

2 

 

Perceive challenges as 

opportunities 

“I learned to improve myself, particularly in solving skills, by 

studying in this module about matrices solving real-life problems 

and being positive”. 

 

3 

 

Replace the word “failing” 

with the word “learning”. 

“Today, I also learned to be positive. Even though I committed 

mistakes, I attempted my best to learn from them. Somehow solving 

involving right triangle is not easy, but I was willing to learn so that 

I tried”. 

 

4 

 

Provide regular 

opportunities for reflection 

“I learned that learning could be everywhere. We could learn 

everything at any time from anyone or ourselves. I learned that to 

learn. We required the effort to accomplish something. Today, I 

learned that learning is the best way to progress. We required to 

perform whatever we could do; we just needed to put some effort to 

do good and solve problems even in real-life experiences”. 



Enhancing Mathematics Learning by Integrating Growth Mindset Principles  

in Ninth-Grade Supplementary Materials 

32 

 

 Themes Description 

 

5 

 

 

Think realistically about 

time and effort 

“Learning fast does not mean learning well, and learning well 

requires allowing time for mistakes. Thinking realistically about the 

time and effort is required to acquire a new skill”. 
 

“In our life, success is the very best thing to acquire but in order to 

succeed, you need to set your goals, put more efforts, learn from 

mistakes, try our best to solve the challenges we have, like in solving 

trigonometric, we need to effort to solve and identify the solution to 

attain the correct answers and try our best to determine the right 

value of it”. 

 

Overall, the students’ mindsets shifting from a fixed mindset to a growth mindset is one of 

the impacts of utilising the developed supplementary materials such as motivational 

activities, reflection activities, or instructional videos. The study results are associated with 

the study of Masterson and Koch (2021). The research result discovered that moving from a 

fixed mindset to a growth mindset required adjustments to the mathematics methods. In this 

study, supplementary materials integrating growth mindset principles are able to help 

students develop a growth mindset in mathematics. 

 

Conclusion 

The supplementary materials developed to integrate growth mindset principles were 

motivational activities, reflection activities, and instructional videos. The students possessed 

significant learning experiences by employing supplementary material, which developed 

procedural fluency and assisted students in shifting from fixed mindsets to growth mindsets 

in mathematics. The students learned to acknowledge and embrace imperfections, view 

challenges as opportunities, acknowledge failures as a key to learning, reflect on learning, 

and think realistically about time and effort. The implementation of the supplementary 

materials affects students’ procedural fluency and mindset in mathematics better than 

conventional teaching in accordance with the findings of this study. In strengthening 

students’ learning and growth mindset, researchers could employ the supplementary materials 

in various areas of learning and with larger sample sizes. 

 

Acknowledgement 

The students, parents, educators, and school principal who participated in the study were 

acknowledged for their participation and cooperation during the implementation and data 

collection. The researchers also appreciate the Department of Science and Technology for 

providing funding and the Department of Education for approving the study in the school. 

 

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