STUDENTS' RESPONSE TO THE USE OF TRACKER
SOFTWARE IN PHYSICS LABORATORY
Perdy Karuru, Silka, Bergita Gela M, Alexander Pakiding,
Enos Lolang
Universitas Kristen Indonesia Toraja, Indonesia
Email: [email protected]
|
KEYWORDS Prakticum, software tracker, projectile
motion |
ABSTRACT This research aims to evaluate how physics
education students respond to the use of tracker software in the
implementation of physics laboratory experiments covering projectile motion.
The study was conducted in the physics laboratory at the Universitas Kristen
Indonesia Toraja (UKI Toraja) and involved 10 (ten) physics education
students. Research data were obtained through questionnaires and analyzed
quantitatively by calculating percentages. The utilization of tracker
software in the implementation of projectile motion experiments enables
students to easily observe and analyze the phenomenon of projectile motion.
Students feel that experiments on projectile motion using tracker software
are relatively straightforward to understand and learn. The results of
student responses to the implementation of physics laboratory experiments
involving tracker software in projectile motion show an approval rate of
64.4%. Therefore, it can be concluded that students exhibit a positive
response and agree with the use of tracker software in physics laboratory
experiments. |
INTRODUCTION
Physical
science is an essential foundation in the field of knowledge and technology,
which facilitates the understanding of natural phenomena and the associated
software development potential. In the process of learning physics, students
are required to apply scientific methods to test the theories that have been
presented. Through practicum, students are expected to be able to test and
apply the theories that have been learned, to improve students' cognitive
abilities and motor skills (Karanggulimu et al., 2017).
Practicum
refers to a series of learning stages where educators guide students to observe
objects, conduct analysis, test theories, and compile conclusions or reports
based on the results of observations made (Rahmawati et al., 2022). In the context of
physics, practicum is usually carried out in a physics laboratory, requiring
adequate equipment to carry out observations.
In modern
times such as the 5.0 era, there are many supporting factors in the learning
process, which include not only classroom learning, but also in practicum
activities, which include the use of video tracker analysis software. Tracker
software has become popular among students of physics study programs, as seen
at Yogyakarta State University, where tracker software has become an important
addition in the implementation of Science Pralktikum 1, accompanied by a guidebook
"Tutorial on Using Tracker Software for Motion Analysis of Objects" (Learning Model Classification | Institute for
Education Development and Quality Assurance - Universitas Amikom Purwokerto,
n.d.). However,
it should be noted that among physics education students at UKI Toraja, the use
of tracker software has not been implemented.
The
advantage of tracker software is its availability as a free download without
the need to pay or subscribe, so this software can be easily accessed, and some
many guides or tutorials allow users to learn it independently (Gultom et al., 2021), (Marliani et al.,
2015), (Pratiwi, 2016). On the other
hand, the weakness of tracker software is its limitation in terms of
compatibility, because it can only be run on computer devices that use Windows
and macOS operating systems (Syaepudin, 2018).
The way
software tracker works involves analyzing videos or images to identify
parameters such as object speed, gravitational acceleration, momentum, and
other elements (Rizki et al., 2021), (Situmeang et al.,
2019). One example of
physical material that can be analyzed using software trackers is the parabolic
movement of an object.
Parabolic
motion involves two velocity components, which are parallel to the x-axis and
perpendicular to the y-axis. The velocity of objects on the x-axis is always
consistent, both in magnitude and direction (Josephine, 2020). Conversely, the
speed of objects on the y-axis will experience deceleration according to the
influence of gravitational acceleration (Santoso &; Winarti, 2019).
In
parabolic motion experiments, we can identify the acceleration of objects, the
speed of objects, the position of objects at a given moment, and generate
relevant linear equations (Raflesiana et al., 2019 ), (Rajagukguk
&; Sarumaha, 2019). Based on the
previous description, the purpose of this study is to assess the response and
evaluation of students to experiments using a tracker software application for
parabolic motion material.
RESEARCH
METHOD
This
research is qualitative-based, but uses quantitative approach methods. Data
were obtained through questionnaires and then analyzed quantitatively by
calculating percentages of questionnaire results that evaluated student
responses to physics practicum involving parabolic motion experiments using
tracker software.
This
research was carried out at the Faculty of Teacher Training and Education,
Physics Education Study Program at Campus 1 of the Indonesian Christian
University of Toraja, located on Jalan Jenderal Sudirman Number 9, Bombongan
Village, Mengkendek District, Tana Toraja Regency, South Sulawesi.
Data in
this study came from a variety of sources, including:
1. The
respondents of this study were students majoring in physics education UKI
Toraja, and the data were collected through questionnaires.
2. Data are
also obtained through direct observation at the location, especially in
practicum observation.
3. Documents
related to this study were also used as data sources.
In this
study, data will be obtained through the use of several information collection
tools, namely:
1. Questionnaire
or questionnaire, which is the main instrument to evaluate student responses.
The questionnaire is designed with questions built on the following indicators:
a. Student
interest in the use of tracker software.
b. The level
of ease in learning and using tracker software.
2. Observation,
which allows researchers to describe the results of analysis about student
behavior during physics practicum using tracker software. Observations focus on
the following specs:
a. Student
interest in practicum activities
b. The level
of understanding of students in the use of tracker software.
3. Interviews
with students, used to get students' views and opinions about the
implementation of the practicum they participated in.
4. Documents,
used to collect data derived from archives and documents relevant to this
research.
The
results of the study obtained from the questionnaire were analyzed using a
descriptive statistical approach with a qualitative approach. Analysis of
questionnaire data is carried out by applying formulas (Karuru et al., 2021):
Information:
p =
percentage
f =
frequency
n = number
of samples
The
percentage values obtained can be interpreted by referring to the parameters
listed in table 1 (Helwig et al., n.d.).
Table 1. Parameters for the interpretation of percentage
values
|
Percentage (%) |
Parameter
Description |
|
0 – 39% 40 – 55% 56 – 75% 76 – 100% |
Strongly
Disagree Disagree Agree Totally Agree |
RESULTS AND
DISCUSSION
After
explaining the background of the research, the theories that support the
research, as well as the research methods used, this chapter will discuss the
results of the study. The results of the study were presented based on data
obtained through questionnaires and observations. In the questionnaire given,
there are 9 (nine) statements related to parabolic motion practicum using
tracker software. The survey results of the nine statements are presented in
table 2.
Table 2.
Questionnaire Data Processing
|
Statement |
STS |
TS |
S |
SS |
||||
|
f |
% |
f |
% |
f |
% |
f |
% |
|
|
1 |
- |
- |
- |
- |
5 |
50% |
f |
% |
|
2 |
- |
- |
- |
- |
8 |
80% |
5 |
50% |
|
3 |
- |
- |
2 |
20 |
8 |
80% |
2 |
20% |
|
4 |
- |
- |
3 |
30 |
5 |
50% |
- |
- |
|
5 |
- |
- |
- |
- |
5 |
50% |
2 |
20% |
|
6 |
- |
- |
2 |
20 |
5 |
50% |
5 |
50% |
|
7 |
- |
- |
2 |
20 |
6 |
60% |
3 |
30% |
|
8 |
- |
- |
- |
- |
8 |
80% |
2 |
20% |
|
9 |
- |
- |
- |
- |
8 |
80% |
2 |
20% |
|
Total |
- |
- |
9 |
90 |
42 |
580% |
2 |
20% |
|
Average |
- |
- |
|
22,5 |
4,7 |
64,4% |
19 |
23,0% |
The explanation of these questions can be illustrated in the form of a diagram
as follows.
Diagram 1. The
percentage of student responses to parabolic motion practicum using tracker
software.
The questions in
the diagram can be explained as follows.
Statement
1,
namely that physics practicum using tracker software is interesting. Of the 10
respondents, half or 50% said they agreed, with the other half as well, or half
expressed stronger approval that strongly agreed.
Statement
2,
that stracker software is very helpful in analyzing parabolic motion experiment
data. This statement received strong support from almost all respondents,
around 80%, while a small percentage of about 20%, even strongly agreed with
the statement. This belief arises because there are various variables of
parabolic motion experiments that can be analyzed using tracker software.
Statement
3,
the use of tracker software in practicum is very simple. Out of 10 respondents,
almost all, about 80%, agreed with this statement. However, a small number of
about 20%, disagree because they feel that adequate computer devices are needed
and also because of the limitations of their use only in motion experiments.
Statement
4,
in my view, the data generated from parabolic motion experiments using trackers
has a high degree of precision. About half of them, about 50%, agreed with this
opinion, in addition, about 20% of respondents, who are a small part, strongly
agree, they argue that the level of accuracy depends on the angle of the video
shot, and the quality of the object and the contrast with the background need
to be maintained so that there are no errors in the analysis of objects.
Statement
5,
parabolic motion experiments that utilize tracker software are considered
simpler when compared to experiments that require the use of physical
equipment. Of the 10 respondents, half or about 50% expressed approval, while
the other half or 50% expressed stronger agreement, namely strongly agree.
Statement
6,
the guide to using trackers is very easy to understand. Of the 10 respondents,
about 50% expressed approval, while about 30% strongly agreed with the
guidelines. On the other hand, about 20% of respondents expressed their
disagreement on the grounds that the explanations in the guide used terms that
were difficult to understand.
Statement
7,
I am interested in deepening the knowledge of tracker software. The vast
majority of respondents, about 60%, indicated approval of this interest, while
a small part, about 20%, strongly supported it. On the other hand, about 20% of
other respondents disagreed, arguing that the use of tracker software requires
adequate devices to run it optimally and to achieve optimal results.
Statement
8,
I feel satisfied when doing parabolic motion experiments with the help of
tracker software. Out of 10 respondents, almost all, that is, about 80%,
expressed approval, while about 20% strongly agreed with this opinion.
Statement
9,
trackers improve understanding of the parabolic motion of an object. About 80%
or almost all respondents expressed agreement with this statement, while about
20% or a small part of them even graphs, curves, and data are very informative.
From the
explanation above, it can be seen how students respond to the use of tracker
software in parabolic motion experiments. In statements 1, 7, and eight, it
discusses the interest and enthusiasm of students towards the use of tracker
software. Almost all responded with approval to all three statements. This
indicates students' interest in using tracker software in physics practicum.
However, the obstacle is the need for adequate computer equipment to maximize
its use.
In
statements 2, 3, and 6, it is discussed about the ease of use of tracker
software. The majority of respondents agreed that the use of tracker software
makes it easier for students to observe and analyze parabolic motion. The
results of this observation show positive respondents and student interest in
the use of tracker software. However, it should be noted that the analysis of
data resulting from the use of tracker software is highly dependent on the
quality of the video used, therefore, it is necessary to video with good
quality and clear contrast between objects and background.
Student
responses to physics practicums involving the use of tracker software in
parabolic motion experiments achieved an approval rate of 64.4%. That way, it
can be concluded that students respond to this physics practicum with a
positive response or agree.
CONCLUSION
The use of
tracker software in parabolic motion experiments makes it easier for students
to observe and analyze parabolic motion. The use of tracker software in
parabolic motion experiments is relatively simple and easy to understand. The
results of student respondents to the physics practicum that integrated tracker
software in parabolic motion experiments showed an approval rate of 64.4%.
Therefore, it can be concluded that students give a positive response or agree
to physics practicum that utilizes tracker software.
Based on
the findings and conclusions that have been presented, the author would like to
provide the following recommendations: 1. It is
recommended that students who take the Physics Education Study Program be more
in-depth in understanding and mastering the use of tracker software as a
learning tool to understand motion phenomena. 2. It is
important to integrate learning about various physics practicum software or
devices in the curriculum to expand the knowledge and qualifications of
prospective physics teachers. 3. This research can
be used as a reference source for future research related to physics practicum
tools, which can contribute to improving mastery of technology and information
in the world of education.
REFERENCES
Gultom, E. S., Sitompul, A. F., & Rezeqi, S. (2021). Kecamatan Silinda
Kabupaten Serdang Bedagai. Seminar Nasional Pengabdian Kepada Masyarakat,
September, 462–467.
Helwig, N. E., Hong, S., & Hsiao-wecksler, E. T. (n.d.).
No 主観的健康感を中心とした在宅高齢者における 健康関連指標に関する共分散構造分析Title.
Josephine, N. E. (2020). Modul Fisika Kelas X KD 3.4.
Direktorat SMA, Direktorat Jenderal PAUD, DIKDAS Dan DIKMEN, 1–39.
Karanggulimu, L., Sudjito, D. N., & Noviandini, D.
(2017). Desain Modul Praktikum Mandiri Tentang Gerak Parabola Menggunakan
Simulasi PhET ”Projectile Motion”. Prosiding Seminar Nasional Pendidikan Sains,
212–214.
Karuru, P., Bundu, P., Anshari, A., & Gani, H. A. (2021).
Students Perception on Physics Learning Interactions. Universal Journal of
Educational Research, 9(5), 1044–1054.
https://doi.org/10.13189/ujer.2021.090517
Klasifikasi Model Pembelajaran | Lembaga Pengembangan
Pendidikan dan Penjaminan Mutu - Universitas Amikom Purwokerto. (n.d.).
Marliani, F., Wulandari, S., Fauziyah, M., & Nugraha, M.
G. (2015). Penerapan Analisis Video Tracker dalam Pembelajaran Fisika SMA Untuk
Menentukan Nilai Koefisien Viskositas Fluida Total Solar Eclipse View project
Socio-Assessment View project. Prosiding Simposium Nasional Inovasi Dan
Pembelajaran Sains 2015 (SNIPS 2015), 2015(June 2015), 333–336.
Pratiwi, R. R. (2016). Penerapan Metode Storytelling Untuk
Meningkatkan Keterampilan Berbicara Siswa Kelas Ii Sdn S4 Bandung. Jurnal
Pendidikan Guru Sekolah Dasar, 1(1), 199–207.
Raflesiana, V., Herlina, K., & Wahyudi, I. (2019).
Pengaruh Penggunaan Tracker Pada Pembelajaran Gerak Harmonik Sederhana Berbasis
Inkuiri Terbimbing Terhadap Keterampilan Interpretasi Grafik Siswa. Gravity :
Jurnal Ilmiah Penelitian Dan Pembelajaran Fisika, 5(1), 1–12.
https://doi.org/10.30870/gravity.v5i1.5207
Rahmawati, A., Supriatno, B., & Anggraeni, S. (2022).
BIODIK: Jurnal Ilmiah Pendidikan Biologi Pengembangan Kegiatan Praktikum
Fermentasi Alkohol dengan Menggunakan Gasometer Volumetrik Sederhana untuk
Mengukur Laju Reaksi Fermentasinya (Improving of Alcohol Fermentation Practice
Activities Using A Simple Volumetric Gasometer to Measure The Rate of The
Fermentation Reaction). Jurnal Ilmiah Pendidikan Biologi, 08, 71–78.
Rajagukguk, J., & Sarumaha, C. S. (2019). Pemodelan Dan
Analisis Gerak Parabola Dua Dimensi Dengan Menggunakan Aplikasi Gui Matlab.
Jurnal Ikatan Alumni Fisika, 4(4), 1. https://doi.org/10.24114/jiaf.v4i4.11378
Rizki, I. A., Citra, N. F., Saphira, H. V., Setyarsih, W.,
& Putri, N. P. (2021). Eksperimen Dan Respon Mahasiswa Terhadap Praktikum
Fisika Non-Laboratorium Menggunakan Aplikasi Tracker Video Analysis Untuk
Percobaan Kinematika Gerak. Journal of Teaching and Learning Physics, 6(2),
77–89. https://doi.org/10.15575/jotalp.v6i2.12640
Santoso, D. M. D., & Winarti, W. (2019). Pengembangan
Modul Fisika Materi Gerak Parabola Berbasis Generative Learning. Prosiding SNFA
(Seminar Nasional Fisika Dan Aplikasinya), 4, 186.
https://doi.org/10.20961/prosidingsnfa.v4i0.38508
Situmeang, B. S., Sudjito, D. N., & Wibowo, N. A. (2019).
Desain Modul Pembelajaran Mandiri Tentang Gerak Parabola Pada Bidang Miring
Tanpa Gesekan Udara. Radiasi : Jurnal Berkala Pendidikan Fisika, 12(1), 9–19.
https://doi.org/10.37729/radiasi.v12i1.16
Syaepudin, M. R. (2018). Menganalisis Sudut Pendulum Pada
Bidang Miring Menggunakan Software Tracker Video. Journal of Teaching and
Learning Physics, 3(2), 14–20. https://doi.org/10.15575/jotalp.v3i2.6553
Copyright holders:
Perdy Karuru, Silka, Bergita
Gela M, Alexander Pakiding, Enos
Lolang (2023)
First publication right:
Devotion - Journal of Research and Community
Service
This
article is licensed under a Creative
Commons Attribution-ShareAlike 4.0 International