a 
  

© 2018 Indonesian Society for Science Educator 116 J.Sci.Learn.2018.1(3).116-121 

 

Received:  29 June 2018 

Revised: 2 August 2018 

Published: 15 August  2018 

 

DOI: 10.17509/jsl.v1i3.11797 

 

Using Physics Education Technology as Virtual Laboratory in Learning 
Waves and Sounds 

Shopi Setiawati Maulidah1, Eka Cahya Prima1* 

1Department of Science Education, Faculty of Mathematics and Science Education, Universitas Pendidikan Indonesia, Indonesia 
 
*Corresponding Author. ekacahyaprima@upi.edu    

ABSTRACT This research was intended to analyze the use of Physics Education Technology (PhET) as a virtual laboratory in 
learning waves and sounds. The analysis was in terms of the implementation of waves on a string student activity as a lesson plan, 
the profile of students’ cognitive, and the profile of science laboratory environment. The method which is used in this research 
was a descriptive method with methodological triangulation as the research design. The sample was taken on the convenient 
situation at grade 8 in an international school in Bandung. According to the analysis of the result, the waves on a string student 
activity can be adopted as the lesson plan with several recommendation to be improved such as in part A, changing some sentences 
in the data table, changing some settings in obtaining data activity, and adding clear example in determining the base and peak 
point in measuring the height of wave at start and at the end. Moreover in part B, adding clear instruction on how to use the ruler 
to measure the wavelength, and changing the picture to obtain the data of wavelength with the picture of simulation with the 
instructed setting are important. In part C, it needs to add the instruction to do the practice session together with the teacher and 
to add the instruction to make the starting point in counting the wave similar in each trial. The use of Physics Education 
Technology (PhET) as a virtual laboratory in learning waves and sounds shows the favorable result on both the cognitive aspect 
and science laboratory environment. 

Keywords Virtual Laboratory, Physics Education Technology (PhET), Waves and  Sounds, Students’ Cognitive, Science 
Laboratory Environment 

1. INTRODUCTION 
Practical work is an essential feature of science 

education (Abraham & Millar, 2008). It can not be 
separated from the learning process of science. Nieh & 
Vaill (2005) stated that practical work is one of the ways to 
enhance students’ understanding. In addition, Frewer & 
Salter (2002) stated that practical work helps students in 
appreciating evidence as basic of science and acquiring 
hands-on skills. Abraham & Millar (2008) stated that 
practical work can be defined as activities in which the 
students manipulate and observe real objects and materials. 
To do this practical work, students have to deal with hands-
on activities. It is clearly known that hands-on activity in 
learning science is usually done in the laboratory, although 
it may be held in the classroom and field as well.  In this 
context, laboratories are an essential component of 
education to make students gain experience (Tüysüz, 2010).  

Physical laboratory is very useful to promote the 
learning process of science, yet provides several problems 
for both students and teacher. Pyatt & Sims (2012) stated 
that physical laboratory experiences may not always 

promote conceptual change. In the real world situation, 
students have no such experiences in conducting 
laboratory activity. Based on Tüysüz (2010), there are 
several problems faced in conducting laboratory activity in 
the physical laboratories such as limitation of facilities, 
limited time allocation, and insufficient laboratory 
condition. Those problems sometimes force the teachers 
to perform laboratory activities in crowded groups. 
Moreover, related to a safety concern, Tatli & Ayas (2013) 
stated that perform laboratory activities in the physical 
laboratory involve risks due to poisonous and unsavory gas 
releases. Considering the problem faced by using the 
physics laboratory to conduct laboratory activities, a virtual 
laboratory may be a preferable alternative to overcome 
those problems (Tatli & Ayas, 2013). Virtual laboratories 
simulate a real laboratory environment and processes and 
are defined as a learning environment in which students 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v1i3.11797 117  J.Sci.Learn.2018.1(3).116-121 
 

convert their theoretical knowledge into practical 
knowledge by conducting experiments (Woodfield, 2005). 
Tiwari & Singh (2011) added that it is designed and 
sequenced in such a manner as to give a real feel of 
performing the experiment. A virtual laboratory may 
sometimes be a preferable alternative, or simply a 
supportive learning environment to physical laboratories 
(Tatli & Ayas, 2013). 

According to Candelas, et. al. (2003), in this era, 
educators have got the accesses to use various kind of 
technology to enhance the effectiveness of the instruction 
process. It supports the use of Virtual laboratory in the 
instruction process. The use of virtual laboratory as an 
alternative to overcome the problems faced in the physical 
laboratory is in line with 21st-century demands. In the 21st 

century, technologies have become commonplace in 
improving and advancing the practice of science education 
because of its potentials of bringing about change in ways 
of teaching practice and learning process (Srisawasdi, 
2012).  

One of the examples of the virtual laboratory is Physics 
Education Technology abbreviated as PhET (Finkelstein et 
al., 2005). PhET is developed by the University of 
Colorado, it is freely available on its website 
(www.phet.colorado.edu). This website consists of more 
than 50 simulations related to physics subject, it can be 
accessed both offline and online. These simulations are 
designed to be highly interactive, engaging, and open 
learning environments that provide animated feedback to 
the user. The simulations model physically accurate, highly 
visual, dynamic representations of physics principles 
(Finkelstein et al., 2005). PhET simulation is equipped with 
its student activity, teacher guidance, and worksheet. 

Many researchers in science have determined that 
carrying out virtual laboratory in the instruction process 
significantly increase students’ achievement (Tüysüz, 2010; 
Tatli & Ayas 2013; Candelas, et. al. 2003) and  have positive 
effect on students’ attitudes (Tuysuz, 2010; Candelas, et. al. 
2003; Pyatt &Sims, 2012). In the process of increasing 
students’ achievement and having a positive attitude in 
learning, students experience an environment which can 
support them to gain the knowledge and have a positive 
attitude. Luketic & Dolan (2013) stated that a student’s 
perception of their learning environment influence how 
and to what extent they learn and retain knowledge. Hence, 
the researcher decided to analyze the students’ cognitive 
and their perception about their science laboratory 
environment in learning waves and sounds using Physics 
Education Technology (PhET) as a virtual laboratory. 
Prima, Putri, & Rustaman (2018) have implemented a 
PhET simulation to improve students' understanding and 
motivation in learning the solar system. Prima, Oktaviani, 
& Sholihin (2018) conducted the learning about electricity 
using Arduino-PhETto exercise STEM literacy. This 
research was conducted to analyze the implementation of 

waves on a string student activity by Esler (2011) a lesson 
plan, to analyze the profile of students’ cognitive and 
science laboratory environment in learning waves and 
sounds using Physics Education Technology (PhET) as 
Virtual Laboratory. The result of this research is expected 
to be used by the teacher as an information to guide 
attempts to improve their classroom. 

 
2. METHOD  

The method that is used in this research was descriptive. 
The term descriptive research refers to studies which are 
known to describe and to interpret what is (Cohen, Manion 
& Morrison, 2007). The location of this research was 
International Junior High School in Bandung. The 
population in this research were 8th-grade students in 
School A. The samples were one class in eighth grade. The 
sampling technique that is used was Convenience 
Sampling. This technique sampling means taking a group 
of individuals who (conveniently) are available for study 
(Fraenkel, Wallen & Hyun, 1993). The Instructional tools 
which was used in this research were Waves on a 
String.swf, it is one of the simulations from PhET which 
can be used to learn transverse wave and it’s properties. 

To obtain the data, the researcher used various kind of 
instruments such as students’ worksheet, cognitive test, and 
SLEI questionnaire. First, to analyze the implementation of 
waves on a string student activity as lesson plan, the analysis 
was in terms of the implementation of the initial lesson plan 
based on field notes and the result show up as the impact 
of the activity done by the students such as the data result, 
and the answer to the question in the worksheet. As the 
result of this analysis, the recommendation in revising the 
lesson plan will be elaborated. Second, to analyze the 
profile of students’ cognitive, the researcher used cognitive 
test consist of 22 questions related to waves properties 
concept. The result of students’ cognitive test is analyzed 
by relating it to the learning process, and then it is being 
calculated until the average of each level of cognitive is 
obtained, after that interpret the average of each cognitive 
level by referring to the criteria described in Table 1. 

The interpretation of the result shows the students 
cognitive in learning waves and sounds with Physics 
Education Technology (PhET). Third, to analyze the 
profile of science laboratory environment, the researcher 
distributed Science Laboratory Environment Inventory 
(SLEI) questionnaire to the sample of this research. This 
questionnaire was developed by Fraser, Giddings & 

Table 1 The criteria for the average of the cognitive aspect 

Percentage of Average (%) Interpretation 

80-100 Very Good 
66-79 Good 
56-65 Fair 
40-55 Poor 
30-39 Failed 

(Arikunto, 2013: 281) 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v1i3.11797 118  J.Sci.Learn.2018.1(3).116-121 
 

McRobbie (1992). This questionnaire was field tested and 
validated simultaneously with a sample of 5447 students in 
269 classes in six different countries including USA, 
Canada, England, Israel, Australia, and Nigeria. It also has 
been cross-validated with 1594 Australian students in 92 
classes (Fraser & McRobbie, 1995), 489 senior high school 
biology students in Australia (Fraser & McRobbie, 1995) 
and 1592 Grade 10 chemistry students in Singapore (Wong 
& Fraser, 1994). The data of students’ perception about 
their science laboratory environment which was obtained 
through questionnaire distribution were processed by 
calculating the average score of each item. The 
interpretation of the result shows the science laboratory 
environment in learning waves and sound with Physics 
Education Technology (PhET) as a virtual laboratory. 

 
3. RESULT AND DISCUSSION  

The data obtained will be analyzed in accordance with 
the research objectives. The first analysis is about the 
implementation of waves on a string student activity as a 
lesson plan. According to waves on a string student activity, 
there were three main parts of the lesson, in each part of 
the lesson, part of the worksheet which was recommended 
to be revised will be elaborated as follows. In Part A, the 
students had to change the scale of amplitude and measure 
the height of wave at the beginning and the end of the 
string. Since the students used similar simulation and 
setting, the data result of each group was supposed to be 
similar. In fact, the data result of each group in this part 
was different each other but lead to the similar tendency, 
means the higher the scale of amplitude, the higher the 
height of wave at the start and at the end of the string. It 
was happened because of parallax error that caused by the 
error in determining the base and peak point of the wave, 
and the wave setting that is used by each group. It is found 
that oscillate setting is more suitable to be used in obtaining 
the data in investigating amplitude instead of pulse setting. 
In this activity, the students also found another difficulty 
namely did not understand some sentences in the data 
table. To sum up the previous explanation, it was found 
that students did not understand some sentences in the 
worksheet, had difficulties in determining base and peak 
point, and Oscillate setting is more suitable to be used in 
this activity. Hence it is recommended to change the 
sentence by easily understood sentence, give students 
example on how to determine base and peak point in 
measuring the height, and use Oscillate setting instead of 
Pulse. 

In Part B, the students had to measure the length of the 
wave at the beginning & the end of the string. The data 
result of each group in this activity was also various because 
each group has a different way to determine the half point 
of the crest in measuring the wavelength. It was found that 
the picture in the worksheet was different from the real 
simulation of the instructed setting. Therefore, It confused 

the students to determine which crest that was being the 
wavelength 2 because the gap between the crest and the 
trough near to the end of the string could not be seen 
clearly. To sum up the previous explanation, it was found 
that students had difficulties in determining half point of 
the crest to be measured as wavelength and the picture in 
the worksheet was different from a real condition one.  
Hence. it is recommended to give clear instruction on how 
to use the ruler to measure the wavelength and change the 
picture in the worksheet with real condition one. 

In Part C, in this part the Students had to change the 
scale of frequency 3 times, in each scale, they had to 
measure the waves passing the certain point at ruler within 
interval time. In this activity, the students did not find any 
meaningful difficulties. Each group data result was slightly 
different from each other because each group has a 
different way to obtain the data. Group 1 obtained the data 
by directly counting the wave as the timer start without 
pause the simulation first, meanwhile, group 2 obtained the 
data by pause the simulation first, and then start the timer, 
after that count the wave by clicking step button. Besides 
that, the determination of the starting point in counting the 
wave was also influenced by their data result, it can be seen 
in Table 2. 

Table 2 shows the display of different starting point 
within the similar time. The wave is counted when it is 
passing the 10 cm point at the ruler. As can be seen in Table 
2, before 1 second the display of starting point 1 has been 

Table 2 Comparison of different starting point in counting the 
waves 

Starting 
point 1 

 

Starting 
point 2 

 

 



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v1i3.11797 119  J.Sci.Learn.2018.1(3).116-121 
 

able to be counted as one wave passing the ruler, 
meanwhile in starting point 2, at a similar time the user has 
not started to count the wave. It has been proved that when 
the user using the starting point 1, the data result would be 
4 waves counted. Meanwhile, when the user using the 
starting point 2, the data result would not be 4. To sum up 
a previous explanation, it was found that group 2 has a 
more homogenous data result than group 1 and the 
determination of the starting point influenced the data 
result. Hence it is recommended to do the practice session 
together with the teacher, since this session was intended 
to make the students understand about the way to obtain 
the data, and it is also recommended to give instruction to 
make the starting point in counting the wave similar in each 
trial. 

The second analysis is about students’ cognitive. The 
data on students’ cognitive was obtained through objective 
which consists of 22 questions. This test was conducted 
within two days at the same time as the research 
implementation. The recapitulation of students’ cognitive 
test result can be seen in Figure 1. The average score of 
each level of cognitive in each day shown by Figure 1 was 
obtained by dividing the average correct answer of each 
level by the number of the question of each level times 100 
%. According to the table 1 about the criteria of cognitive 
test average by Arikunto (2013), the students cognitive 
result (can be seen in figure 1) in level of C-2 
(understanding) and C-4 (analyzing) were considered in the 
criteria of very good both in day 1 and day 2 of research 
implementation. Meanwhile, the student's cognitive result 
in a level of C-3 (applying) was considered in the criteria of 
good on day 1, and very good on day 2 of research 
implementation. 

This favorable result of cognitive aspect was supported 
by the previous research which stated that the use of virtual 
laboratory increased students’ achievement levels (Tüysüz, 
2010). The previous research also suggested that virtual 
laboratories are at least as effective as real laboratories in 

terms of introducing the students with the experiment 
process (Yu et al.; Tatli & Ayas, 2013). 

The third analysis is about science laboratory 
environment. The data of science laboratory environment 
is obtained through the Science Laboratory Environment 
Inventory (SLEI) questionnaire which was distributed to 
each sample of this research. The average score of each 
scale as the result can be seen in Table 3.  

Table 3 shows the result of the SLEI questionnaire 
distributed to the sample of this research. It shows the 
average item score of each scale. The first scale is Students 
Cohesiveness, this scale means the extent to which students 
know, help, and are supportive of one another (Fraser, 
Giddings & McRobbie, 1992). The average score obtained 
for this scale is 4.75 with the interpretation of often 
happened. It means the learning process using Physics 
Education Technology (PhET) as virtual laboratory 
supported the students’ cohesiveness. This virtual 
laboratory activity demanded the students be able to know, 
help, and support one another since they had to work 
within the group. For example, in one of the activities using 
this virtual lab, the students helping one another by 
dividing the job-desk.  

The second scale is Open-Mindedness. This scale has 
the meaning of the extent to which the laboratory activities 
emphasize an open-ended divergent approach to 
experimentation (Fraser, Giddings & McRobbie, 1992). 
The average score on this scale is as much as 3.73, with the 
interpretation of sometimes happened. This scale is related 
with students’ exploration in conducting the virtual 
laboratory activity. In this virtual laboratory activity there 
was instruction given to the students in conducting the 
virtual laboratory activity, hence sometimes the teacher 
decide the best way to carry out the virtual laboratory 
activity and sometimes the teacher asks the students to 
explore the simulation by themselves. This result is in line 
with the previous research which stated that the students 
were given the opportunity to explore and manipulate 
experimental variables by virtual experiences (Pyatt & Sims, 
2012). 

The third scale in the SLEI questionnaire is Integration. 
This scale has the meaning of the extent to which the 
laboratory activities are integrated with non-laboratory and 
theory classes (Fraser, Giddings & McRobbie, 1992). The 
average score of this scale is as much as 4.77, it was the 

Table 3 The average score for each scale of SLEI 

No Attitude Scale 
Max Item 
Score 

Average Item 
Score 

1 Students' Cohesiveness 5 4.75 

2 Open-Endedness 5 3.73 

3 Integration 5 4.77 

4 Rule Clarity 5 4.56 

5 Material Environment 5 4.74 

 

 
Figure 1 Recapitulation of the cognitive test result 

93.75 78.
125

100
93.75

0

50

100

150

Day 1 Day 2

A
c
h

ie
v
e
m

e
n

ts

Implementation days

C-2 C-3 C-4



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v1i3.11797 120  J.Sci.Learn.2018.1(3).116-121 
 

highest average score compared to the other scale. It has 
an interpretation of often happened. It means the students 
often used a theory which has been learned in regular 
science class to conduct virtual laboratory activity. Even, 
this virtual laboratory activity helped them to understand 
the theory covered in regular science class as described in 
one of the statements in the questionnaire. 

The fourth scale is Rule Clarity, with the meaning of the 
extent to which behavior in the laboratory is guided by 
formal rules (Fraser, Giddings & McRobbie, 1992). The 
average score on this scale is as much as 4.56, with the 
interpretation of often happened. The students were given 
the rule before they conducted the virtual laboratory 
activity. Since they would not deal with dangerous 
materials, hence they were only given rule about using the 
laptop as the instructional tools in conducting virtual 
laboratory activity. The rule forbids them to open any other 
application besides adobe flash player within the learning 
process. It made them focus on the virtual laboratory 
activity. 

The last scale is Material Environment which asks the 
students about the adequacy of laboratory equipment and 
materials (Fraser, Giddings & McRobbie, 1992). Since this 
virtual laboratory activity only used laptop and PhET 
simulation as the equipment, the average score of this scale 
is 4.74 with the interpretation of often happen. Means, the 
equipment used in this virtual laboratory activity was 
adequate enough to support the learning process using 
Physics Education Technology (PhET) as a virtual 
laboratory. 

 
4. CONCLUSION 

Based on the result and discussion elaborated, it can be 
concluded that Waves on string student activity by Esler 
(2011) can be adopted as a lesson plan with several aspects 
which are recommended to be improved as follows. In Part 
A, changing some sentences in the data table is required in 
order to make it easier to be understood by the students, 
changing some settings in obtaining data activity is 
required, and adding a clear example is required on how to 
determine the base and peak point in measuring the height 
of wave at the start and at the end. In Part B, adding clear 
instruction is required on how to use the ruler to measure 
the wavelength, and changing the picture is required to 
obtain the data of wavelength with the picture of 
simulation with the instructed setting. In Part C, adding 
instruction is required to do the practice session together 
with the teacher, and adding instruction to make the 
starting point in counting the wave similar in each trial. To 
sum up, the use of Physics Education Technology (PhET) 
as a virtual laboratory in learning waves and sounds shows 
the favorable result on both the cognitive aspect and 
science laboratory environment. 

 

REFERENCES   
Abrahams, I., & Millar, R. (2008). Does practical work really work? A 

study of the effectiveness of practical work as a teaching and 
learning method in school science. International Journal of Science 
Education, 30(14), 1945-1969. 

Arikunto, S. (2013). Dasar – Dasar Evaluasi Pendidikan. Jakarta: Bumi 
Aksara. 

Candelas, F. A., Puente, S. T., Torres, F., Ortiz, F. G., Gil, P., & 
Pomares, J. (2003). A virtual laboratory for teaching robotics. 
Complexity, 1(10), 11. 

Cohen, L., Manion, L., & Morrison, K. (2007). Research Methods in 
Education. New York: Taylor & Francis e-library. 

Esler, J. (2011). Waves on A String Students Activity. [Online]. Retrieved 
from http://phet-downloads.colorado.edu/files/activities/zip/ 
Accessed on January 1, 2018. 

Finkelstein, N. D., Adams, W. K., Keller, C. J., Kohl, P. B., Perkins, K. 
K., Podolefsky, N. S., ... & LeMaster, R. (2005). When learning 
about the real world is better done virtually: A study of substituting 
computer simulations for laboratory equipment. Physical Review 
Special Topics-Physics Education Research, 1(1), 010103. 

Fisher, D., Henderson, D., & Fraser, B. (1995). Interpersonal behaviour 
in senior high school biology classes. Research in Science Education, 
25(2), 125-133. 

Fraenkel, J. R., Wallen, N. E., & Hyun, H. H. (1993). How to design and 
evaluate research in education (Vol. 7). New York: McGraw-Hill. 

Fraser, B. J., Giddings, G. J., & McRobbie, C. J. (1992). Assessing the 
Climate of Science Laboratory Classes. National Key Centre for School 
Science and Mathematics, 8, 1-13. 

Fraser, B. J., & McRobbie, C. J. (1995). Science Laboratory Classroom 

Environments at Schools and Universities: A Cross‐National 
Study∗. Educational Research and Evaluation, 1(4), 289-317. 

Frewer, L., & Salter, B. (2002). Public attitudes, scientific advice and the 
politics of regulatory policy: the case of BSE. Science and public policy, 
29(2), 137-145. 

Luketic, C. D., & Dolan, E. L. (2013). Factors influencing student 
perceptions of high-school science laboratory environments. 
Learning environments research, 16(1), 37-47.  

Nieh, J., & Vaill, C. (2005). Experiences teaching operating systems 
using virtual platforms and linux. ACM SIGCSE Bulletin, 37(1), 
520-524. 

Prima, E. C., Oktaviani, T. D., & Sholihin, H. (2018). STEM learning on 
electricity using arduino-phet based experiment to improve 8th 
grade students’ STEM literacy. Journal of Physics: Conference Series. 
1013(1), 012030. 

Prima, E. C., Putri, A. R., & Rustaman, N. (2018). Learning Solar System 
Using PhET Simulation to Improve Students' Understanding and 
Motivation. Journal of Science Learning, 1(2), 60-70. 

Pyatt, K., & Sims, R. (2012). Virtual and physical experimentation in 
inquiry-based science labs: Attitudes, performance and access. 
Journal of Science Education and Technology, 21(1), 133-147. 

Srisawasdi, N. (2012). Student teachers’ perceptions of computerized 
laboratory practice for science teaching: a comparative analysis. 
Procedia-Social and Behavioral Sciences, 46, 4031-4038. 

Tatli, Z., & Ayas, A. (2013). Effect of a Virtual Chemistry Laboratory on 
Students' Achievement. Journal of Educational Technology & Society, 
16(1),159-170.  

Tiwari, R., & Singh, K. (2011). Virtualisation of engineering discipline 
experiments for an Internet-based remote laboratory. Australasian 
Journal of Educational Technology, 27(4), 671-692. 

Tüysüz, C. (2010). The Effect of the Virtual Laboratory on Students' 
Achievement and Attitude in Chemistry. International Online Journal 
of Educational Sciences, 2(1). 37-53. 

Wong, A. F., & Fraser, B. J. (1994). Science Laboratory Classroom 
Environments and Student Attitudes in Chemistry Classes in 
Singapore. Annual Meeting of the American Educational Research 
Association.  



Journal of Science Learning  Article 
 

DOI: 10.17509/jsl.v1i3.11797 121  J.Sci.Learn.2018.1(3).116-121 
 

Woodfield, B. (2005). Virtual chemlab getting started. Pearson Education 
website. 25, 2005.