Universitas Muhammadiyah Malang, East Java, Indonesia 

 

JPBI (Jurnal Pendidikan Biologi Indonesia) 
 

p-ISSN 2442-3750, e-ISSN 2537-6204 // Vol. 6 No. 3 November 2020, pp. 367-374  

 

 

         10.22219/jpbi.v6i3.12081                              http://ejournal.umm.ac.id/index.php/jpbi                     jpbi@umm.ac.id  367 

Research Article  

Students' learning motivation and cognitive 
competencies in the PP and PBL models 
 

Nurul Hidayati a,b,1,, Didimus Tanah Boleng b,2, Krishna Purnawan Candra b,c,d,3,*   
a Public Islamic Senior High School (MAN) 2 Samarinda, Jl.Harmonika No.98, Samarinda 75113, Indonesia 
b Biology Education Graduate Study Program, Faculty of Teacher and Training Education, Mulawarman University, Jl. Muara Pahu,  

   Kampus Gunung Kelua, Samarinda 75119, Indonesia 
c Dept.Agricultural Product Technology, Faculty of Agriculture, Mulawarman University, Jl. Tanah Grogot, Kampus Gunung Kelua,  

  Samarinda 75119, Indonesia 
d Graduate Program of Mulawarman University, Jl. Sambaliung, Kampus Gunung Kelua, Samarinda 75119, Indonesia 
1 nurulmusyaffa28@gmail.com; 2 didimus.tanahboleng@yahoo.com; 3 candra@faperta.unmul.ac.id* 

* Corresponding author 

 

INTRODUCTION 

Implementation of curriculum 2013 at primary and high school in Indonesia since 2014, push the 
transformation of the learning process from the teacher center to the student center. The main reason is that 
nowadays, learning activities are designed to facilitate the student to explore their ability to be creative, 
innovative, and able to collaborate (Kementerian Pendidikan dan Kebudayaan Republik Indonesia, 2014). 
Understandably, there is still not enough academic atmosphere among students in supporting the student-
center learning process, so that active effort is needed to create a good environment in helping the student to 

A R T I C L E  I N F O   A B S T R A C T   

 

Article history 
Received May 4, 2020   

Revised June 14, 2020 

Accepted November 17, 2020 

Published November 30, 2020 

 The learning model is one of the critical factors in boosting student to have good 
learning motivation (LM) and cognitive competencies (CC). In two academic years 
(2016-2017), only 19.6% of Senior High School (SHS) students in Samarinda passed 
minimal competence in Biology subject. This research was conducted to find out a 
better learning model in Biology subject to replace the conventional learning (CL) 
model. A quasi-experiment using three learning models, i.e. Problem Posing (PP), 
Problem-based Learning (PBL), and CL, were conducted in all three 11th grade student 
classes at Public Islamic SHS (PISHS) I Samarinda in the period of odd semester of 
2018/2019 academic year. The LM and CC data were collected by questionnaires, each 
has 40 and 9 problems, respectively.  The LM and CC data were analyzed by ANOVA 
and ANCOVA continued by comparison test using Bonferroni test (p< 0.05), 
respectively. The results showed that the CL model could increase the CC, but not 
improve LM. However, PP and PBL model were significantly more effective (p< 0.05) in 
increasing both the CC and LM. The PP is superior in improving the LM, while the PBL 
is superior in gaining the cognitive competence.  

 
 

Copyright © 2020, Hidayati et al  

This is an open access article under the CC–BY-SA license 

    

 

 
Keywords 
Problem posing 

Problem-based learning 

Learning motivation 

Cognitive competencies 

 

  

 
How to cite:  Hidayati, N., Boleng, D. T., & Candra, K. P. (2020).  Students' learning motivation and cognitive competencies in the 

PP and PBL models. JPBI (Jurnal Pendidikan Biologi Indonesia), 6(3), 367-374. doi: https://doi.org/10.22219/jpbi.v6i3. 
12081 

 

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 Vol. 6, No. 3, November 2020, pp. 367-374 

 

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have dynamic learning with eventually comfortable circumstances. On the other hand, active learning and 
student-centered pedagogy improved student performance and achievement in Biology subject (Corkin et al., 
2017; Derting & Ebert-May, 2010; Mueller et al., 2015). However, this transformation is going to slow because 
of the lacking of innovations in the school to try new learning models, which can facilitate the student center 
learning process to take place, including in Samarinda. The impact is the students show low motivation in the 
learning activity and cognitive competence.  

A preliminary study on two academic years (2016/2017 and 2017/2018) of students with majoring in 
mathematics and science from 6 senior high schools of total 22 senior high schools in Samarinda in year of 
2018 (Direktorat Jenderal Pendidikan Dasar dan Menengah Kementerian Pendidikan dan Kebudayaan, 2019), 
which were randomly observed, showed that level of completeness in learning biology is very low (the average 
was 19.6%). Based on interviewed, the factor that make student get low score because conventional learning 
method with teacher as study centre was still used. The learning activities were not varied and monotonous, 
caused the implication that students showing low attention and motivation during learning activities. Therefore, 
the application of innovative learning that could increase student motivation needs to be implemented in biology 
learning. 

Problem posing (PP) is a learning model that facilitates the student to explore the discussed subject by 
developing questions or problems that are to be solved (Rehorek, 2004). The PP is a well-known approach in 
chemistry (Iriani & Hidayah, 2017), mathematics (Bonotto, 2010), and physic discipline (Rufaida & Sujiono, 
2013). However, Jungck (1985) gave a challenge to education practitioners in using the PP approach in biology 
education to answer the ecological and evolutionary complexity of our problems. 

On the other hand, Problem-based Learning (PBL) is promising pedagogy model in science since it 
performs the value and learning outcomes in which student has the autonomy to understand the nature-of-
science, able to collaborate, and can generate knowledge (Allchin, 2013). Several research also showed that 
PBL could significantly increase students’ achievement than conventional learning models in biology class 
(Kan’an & Osman, 2015; Taşoğlu & Bakaç, 2010). 

Despite the benefits of PBL and PP, many teachers in Indonesia still rarely implement this learning model in 
their biology classes. One potential effort to encourage teachers to implement these learning models is by 
increasing the number of studies examining the benefits of these two lessons. In fact, studies that examine PBL 
have been conducted frequently. However, these studies often only examine the different effects of PBL and 
conventional learning (Kan’an & Osman, 2015; Taşoğlu & Bakaç, 2010). Some researchers also compare PBL 
with other learning models, such as with project-based learning (Husna et al., 2019; Sari, 2018). In addition, 
there were no studies that compare PP and PBL on students' motivation and cognitive competence. Therefore, 
the aim of this study was to determine the effect of the PP and PBL model in Biology subject of Public Islamic 
Senior High School (PISHS) students on cognitive competence and learning motivation. The student at PISHS 
has to have 19 subjects, which are six items more than the students at regular Senior High School. This 
condition makes the students at PISHS feel tired physically and mentally, so they have low motivation in 
learning biology. Because of that reason, a study on learning motivation at PISHS following the implementation 
of the student-center learning process will be valuable information in the effort of increasing student learning 
motivation, especially in Biology subject. 

METHOD 

A quasi-experiment was conducted on three 11th Classes of PISHS I, Samarinda, in odd semester of 
2018/2019 academic year in structure and function of plant tissue subject. Different learning models, i.e., PP, 
PBL, and conventional, were applied at a different class. The student number of PP and conventional classes 
were each 36 students, while the PBL class has 37 students. Learning motivation (LM) and cognitive 
competence (CC) were observed by questionnaire and test, respectively, at the beginning and at the end of the 
period of learning-subject, which were taught in four class-meeting. The topic taught from the first to the fourth 
meeting were meristem, leaf structure and function, structure and function of root and stem, and anatomy on 
monocots and dicot and tissue culture, consecutively. 

All of the statements in the questionnaire for learning motivation (40 questions) and test for cognitive 
competence (9 problems) passed the validity test with the r between 0.484-0.790 and 0.547-0.667, 
respectively, while rtable is 0.344. Both instruments showing an excellent score in the reliability test of 0.956 and 
0.711 for the questionnaire of learning motivation and cognitive competence, respectively. The survey and 
problem for learning motivation and cognitive skills are shown in Table 1 and Table 2, respectively. 

The score for the learning motivation (LM) questionnaire is 40 and 200 for a maximum and minimum score, 
respectively. Data for learning motivation (the gain of LM, score of LM at the beginning of the experiment – 
score of LM at the end of the test) were analyzed by ANOVA because the data showed significantly different 



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(p=0.000) between the three classes. The ANOVA was continued by comparison test using Bonferroni test 
(SPPS v.22). For descriptive analysis, the LM achievement data were then categorized to a Likert scale of low 
(1), medium (2), and high (3) for the score of 40-93, 94-147, 148-200, respectively (Sudjana, 2015). 

Table 1. Characteristics of learning motivation questionnaire (Indicators and type of statements) 

Indicators 
Question’s number 

Positive Negative 

Persevering in the task 1, 2, 4 3, 5 
Not easily discourage 6, 8, 10 7, 9 
Showing interest 11, 13, 15 12, 14 
Happy to work independently 16, 17,18, 19 20 
Quickly bored with routine tasks 21, 23, 24 22, 25 
Can depend on his opinion 26, 27, 29 28, 30 
Not quickly go of things that are believed 31, 33, 35 32, 34 
Happy to find and solve problems 36, 37, 38, 39 40 

The statements 

1 I took my Biology assignment seriously 
2 I completed the Biology assignment on time. 
3 For me, the essential thing in solving the Biology problem or assignment on time without caring about the result that I will get. 
4 Every time I have a Biology assignment, I immediately work on it. 
5 I am not serious in solving Biology problems or assignments given by the teacher. 
6 If my Biology score is terrible, I will continue to study so that the grade becomes good. 
7 If my Biology score is terrible, I do not want to study anymore 
8 I feel satisfied if I can work on Biology problems and getting good grades. 
9 I will not do the problematic Biology problems 
10 If I encounter a problematic Biology problem, I will try to work on it until I find the answer. 
11 I always listen to the Biology teacher’s explanation well. 
12 I prefer to talk with friends and do not listen to the teacher when he/she explains 
13 I always ask the teacher about the Biology subject that I do not understand yet. 
14 I am lazy to ask the teacher about Biology subject that I do not understand. 
15 I always answer Biology questions that teachers ask 
16 I always do my Biology assignments given by the teacher 
17 I copy my friend’s answers in doing Biology assignments and questions. 
18 I can complete the Biology assignment on my own. 
19 I prefer to work on Biology assignments with friends. 
20 I never copy a friend’s answer because I trust my answers. 
21 I enjoy studying Biology because the teacher is diligent in teaching. 
22 In my opinion, learning Biology is annoying because the teacher only delivers the materials through lecturing. 
23 I enjoy studying Biology because the teacher uses instructional media to explain the subject. 
24 I enjoy studying Biology because there is not any tense atmosphere for the teacher. 
25 I feel bored in studying Biology because I only take notes while learning. 
26 I always give an opinion when there is a discussion in the Biology lesson. 
27 If different responses arise, I will respond to them. 
28 I stay silent and do not give any opinion. 
29 I try to defend my opinion during the discussion. 
30 I’m always nervous about expressing my opinion in front of my friends. 
31 My friend’s answers do not easily influence me. 
32 If my answer is different from my friend’s, I will change my answer to be the same as theirs. 
33 I believe I can get the best score on my Biology assignments because I did well. 
34 I am not sure about my answer if my answer is different from my friend’s. 
35 Every time I’m solving a Biology problem, I have a target above average because I believe I can do it correctly. 
36 I was challenged to work Biology problems that were considered difficult by friends. 
37 I’m glad to have Biology assignments from a teacher. 
38 If there are Biology assignments in the book that haven’t been worked on, I will do it. 
39 I look for other suitable sources to finish my Biology assignments. 
40 I prefer working on easy Biology assignments than difficult ones. 

Note: each indicator consists of 5 statements. The answers of the positive comments were 5, 4, 3, 2, and 1 for strongly agree, agree, 
neutral, not agree, firmly not accept, respectively, while strongly not agree, not agree, neutral, agree, and strongly agree for the 
negative statements. 

The score for cognitive competence is 0-100, which for each question was calculated by equation [1]. Data 
were analyzed by ANCOVA continued by comparison test using Bonferroni test (SPSS v.22). For descriptive 
analysis, the CC data were categorised to the Likert scale of very low (1), low (2), medium (3), high (4) and very 
high (5) for the score of CC < 20, 20 ≤ CC < 40, 40 ≤ CC < 60, 60 ≤ CC < 80, 80≤ CC, respectively (Sudjana, 
2015). 



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Table 2. Questions for cognitive competence 

No Questions Weight Score 

1 Describe three differences between meristem and permanent tissue 6 0-6 
2 Describe three types of meristem tissues according to its location 6 0-6 
3 Write down three components of each xylem and phloem 12 0-6 
4 Describe the types of an epidermal derivative of the plant below 6 0-6 
5 Describe the function of leaf component structure from the top to the bottom 10 0-6 
6 Please write down the type of root shape, external structure of a leaf, and part number of a 

flower of monocots and dicot plants 
24 0-6 

7 Write down the name of the designated part in the cross-section of the stem 12 0-6 
8 Describe the advantages of tissue culture technique in plant nurseries 12 0-6 
9 Write down three types of tissue culture that you know and describe each type 12 0-6 

Note: the answer to each question consists of six items. The score for each question is 6, 5, 4, 3, 2, 1, and 0 for a solution that has 6, 
5, 4, 3, 2, 1, and 0 correct items. 

 

RESULTS AND DISCUSSION 

PBL and PP are innovative models whose application still needs to be optimized in Indonesia. In this study, 
the two models were tested for their effect on LM and CC of PISHS students. Student-centered learning using 
PP and PBL models showing suitable and comfortable for the students than the conventional ones. Both 
learning models significantly (p < 0.05) improve the LM (Table 3) and CC (Table 5) levels. Student-centered 
learning opens the opportunity of discussion in groups so that the students share ideas or opinions. 

Learning models affected significantly (p = 0.001) on the students’ LM (Table 3). The PP and PBL 
increased the number of the student having a high level of LM achievement, while the conventional learning 
model showed the opposite result. The score of LM achievement form the three classes also emphasize this 
trend. In student-centered learning, the students are going into groups, which are arranged that students with 
high academic abilities can help students with low academic skills (Qomariah, 2016). This condition 
encourages the low motivated students to be more active in the discussion within groups by helping highly 
motivated students. 

The PP and PBL improve the LM with the same power. However, the PP showed more reliable capacity in 
enhancing the LM. The mean difference between PP and PBL to the Conventional model is 6.917 (p=0.001) 
and 5.089 (p = 0.015), respectively (Table 4). It means that PP is more effective in improving the student LM in 
the structure and function of plant tissue subjects. The PP seems to give a more exciting learning environment 
by the students, as stated by Uno (2011) that someone will be motivated to do activities when he can maintain 
his sense of pleasure. 

PBL is able to present a series of interesting learning activities. By presenting problems at the beginning of 
learning, students will be challenged to solve these problems. In addition, by working in groups, students will be 
more motivated to participate in learning. However, if students only listen to the teacher's explanation during 
learning, students will get bored faster so they will lose their motivation to learn. 

Table 3. Effect of learning models on Learning Motivation (LM) of the student in the structure and function of plant tissue subject at 
11th class 

Level of LM achievement Problem Posing Problem-Based Conventional 

At the beginning of the experiment (P) (n; %) 
High 7; 19.4 9; 24.3 7; 19.4 
Medium 29; 80.6 28; 75.7 29; 80.6 
Low 0; 0 0; 0 0; 0 
Mean±SD 137.00±1.74 138.46±1.72 136.92±1.77 

    
At the end of the experiment (Q) (n; %) 

High 14; 38.9 12; 32.4 5; 13.9 
Medium 22; 61.1 25; 67.6 31; 86.1 
Low 0; 0 0; 0 0; 0 
Mean±SD 141.64±2.03 141.27±1.71 134.64±1.95 

    
Shifting of LM achievement level, Increasing (+) / decreasing (-) (P - Q) (n; %) 

High +7; +19.4 +3; +8.1 -2; +5.6 
Medium -7; -19.4 -3; -8.1 +2; -5.6 
Low - - - 



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Different from PBL, which is commonly used in Biology education (Mutakinati et al., 2018; Yahya, 2014), PP 
is very rarely used in Biology education. However, this study demonstrated that the PP is a challenge learning 
model to be used in Biology education, as suggested by Jungck (1985), especially to improve the students 
learning motivation. 

Motivation is an important factor in the learning process (Gbollie & Keamu, 2017). High motivation 
correlates with high learning efficacy and student interest in the subjects they take (Daskalovska et al., 2012; 
Redondo & Martín, 2015). When students are motivated to learn, they will seriously follow and study the 
material taught in the subject. This condition will optimize students’ learning success and academic 
achievement. Therefore, the significant effect of PBL and PP on LM is expected to be followed up by teachers 
to implement these two learning models.  

Table 4. Pairwise comparison for LM achievement gain 

Learning Model (I) 
Learning 
Model (J) 

Mean Difference 
(I-J) 

SE p 
95% Confidence Interval for Difference 

Lower Bound Upper Bound 

PP PBL 1.8281 1.77084 0.913 -2.4796 6.1358 

Conventional 6.9167* 1.78293 0.001 2.5796 11.2538 

PBL PP -1.8281 1.77084 0.913 -6.1358 2.4796 

Conventional 5.0886* 1.77084 0.015 0.7809 9.3963 

Conventional PP -6.9167* 1.78293 0.001 -11.2538 -2.5796 

PBL -5.0886* 1.77084 0.015 -9.3963 -0.7809 

Note: Problem Posing and Conventional (Control Class) are each 36 students, while Problem Based Learning is 37 students. Data 
were analyzed by ANOVA (based on observed means) continued pairwise comparison test. *) The mean difference is significantly 
different (Bonferroni test at a level of 0.05), SE = Standard Error. PP = Problem Posing, PBL = Problem-Based Learning. LM 
achievement data were then categorized to a Likert scale of low (1), medium (2), and high (3) for the score of 40-93, 94-147, 148-200, 
respectively. 

Table 5. Effect of learning models on Cognitive Competence (CC) of the student in the structure and function of plant tissue subject at   
11th class 

Characteristics Problem Posing Problem Based Learning Conventional 

Pre-test    
Min 17 17 17 
Max 39 38 38 
Mean±SD 24.78±0.75 27.14±0.78 24.00±0.69 

    
Post-test    

Min 77 77 76 
Max 92 100 79 
Mean±SD 80.86±0.74 84.64±1.13 77.53±0.19 

    
Increasing (+) of CC result level of students (Post-test – Pre-test) 

Min +60; 353% +60; 353% +59; 347% 
Max +53; 136% +62; 163% +41; 108% 
Mean +56.08; 226% +57.50; 212% +53.53; 223% 

 

The learning models affected significantly (p = 0.000) on students’ CC (Table 5). The PP and PBL boosted 
the CC level higher than the conventional learning model (Table 6). The most effective learning model affected 
the increase of CC level (Table 6), and the score (Table 7) is PBL, followed by PP and Conventional. The PBL 
boosted the CC level of the student to a very high level of 75.5%. It is higher than PP that only raised the 
student CC level to a very high level of 45.4%. The conventional learning model was only able to increase the 
CC level to a high level (100%). PP improved the CC score in the range of 0.572-6.125 against the 
Conventional learning model, while PBL enhanced in a variety of 4.316-10.046. The PBL is superior in boosting 
the CC score than PP. The PBL improved the CC score in the range of 1.017-6.648 against PP. This study 
demonstrated that PBL is the most effective among the three learning models in structure and function on 
tissue plant subjects. 

Table 6. Distribution of CC level (n; %) in the three different learning model classes 

Leve of CC 
score 

Problem Posing Problem Based Learning Conventional 

Pre-test Post-test Pre-test Post-test Pre-test Post-test 

Very low 3; 8.3 0; 0 2; 5.4 0; 0 5; 13.9 0; 0 
Low 33; 91.7 0; 0 35; 95.6 0; 0 31; 86.1 0; 0 
Medium 0; 0 0; 0 0; 0 0; 0 0; 0 0; 0 
High 0; 0 20; 55.6 0; 0 9; 24.3 0; 0 36; 100 
Very high 0; 0 13; 45.4 0; 0 28; 75.7 0; 0 0; 0 



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Table 7. Pairwise comparison for CC score 

(I) Learning 
Model 

(J) Learning Model 
Mean Difference 

(I-J) 
SE p 

95% Confidence Interval for Difference 

Lower Bound Upper Bound 

PP PBL -3.833* 1.157 0.004 -6.648 -1.017 
Conventional 3.348* 1.141 0.012 0.572 6.125 

PBL PP 3.833* 1.157 0.004 1.017 6.648 
Conventional 7.181* 1.178 0.000 4.316 10.046 

Conventional PP -3.348* 1.141 0.012 -6.125 -0.572 
PBL -7.181* 1.178 0.000 -10.046 -4.316 

Note: Problem Posing and Conventional (Control Class) are each 36 students, while Problem Based Learning is 37 students. Data 
were analyzed by ANCOVA (based on estimated marginal means) continued by pairwise comparison test, *) The mean difference is 
significantly different (Bonferroni test at a level of 0.05), SE = Standard Error. PP = Problem Posing, PBL = Problem-based Learning. 
Cognitive competence (CC) data (0-100) were categorised to the Likert scale of very low (1), low (2), medium (3), high (4) and very 
high (5) for the score of CC < 20, 20 ≤ CC < 40, 40 ≤ CC < 60, 60 ≤ CC < 80, 80≤ CC. 

By the PP learning model, the students experienced to have difficulties in focusing on generating questions 
in-line with the subject matter discussed, which burdened students in mastering the basic knowledge that they 
should have. Chin & Kayalvizhi (2002) reported the same cases  while implemented the PP learning model so 
that the teacher should develop the method that can help the student to pose problems and questions. 
However, Rufaida & Sujiono (2013) showed a different indication on the physic subject, which is the PP 
learning model showed better performance than learning cycle 5E. 

On the other hand, PBL facilitates the students to develop their knowledge based on the problem given to 
them that in-line with the subject. Many reports show that the PBL can improve the cognitive competence in 
biology or science subjects effectively (Mutakinati et al., 2018; Ratini et al., 2018; Suciati et al., 2020; Taşoğlu & 
Bakaç, 2010; Wulansari et al., 2018), besides the PBL can improve the psychometric skills of the students 
(Sumarni et al., 2016). 

The series of learning syntax in PBL is the reason why PBL can optimally empower students' CC. When 
students are given problems at the beginning of learning, they must use their thinking skills to deal with these 
problems. Thinking skills have been widely reported as predictors of student cognitive learning outcomes 
(Miharja et al., 2019; Mite & Corebima, 2017; Wicaksono, 2014; Wulandari, 2018). In addition, group discussion 
activities will also optimize the cognitive development of students because there is an exchange of knowledge 
and opinions (Chang & Mao, 2010; Nurulwati et al., 2020). On the other hand, this condition will be difficult to 
realize when students follow the lecture-based learning method.  

CONCLUSION 

In the case of Senior High School in Samarinda, especially at Public Islamic Senior High School, PP and 
PBL models showed superior in increasing learning motivation and cognitive competence in structure and 
function of plant tissue subject of 11th Class than conventional learning model; however, both learning models 
have different effectiveness. The PP learning model showed more effective in increasing the learning 
motivation, while the PBL model showed more effective in improving cognitive competence.  

Based on the findings obtained in this study, PBL and PP is recommended to be increasingly implemented 
in biology learning in various schools in Indonesia. By applying these two learning models, student 
competencies are expected to be able to develop more optimally. In addition, studies that examine the effect of 
the PBL + PP combination are also recommended for future research. The addition of other dependent 
variables based on 21st Century skills also needs to be studied. 

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