=Paper=
{{Paper
|id=Vol-2555/paper33
|storemode=property
|title=Smartphone in school physics: a case study for the experimental obtaining of the
acceleration of gravity in the analysis of a spring through a didactic approach
|pdfUrl=https://ceur-ws.org/Vol-2555/paper33.pdf
|volume=Vol-2555
|authors=Jhon Alfredo Silva Alé
}}
==Smartphone in school physics: a case study for the experimental obtaining of the
acceleration of gravity in the analysis of a spring through a didactic approach==
https://ceur-ws.org/Vol-2555/paper33.pdf
Smartphone in school physics: a case study for the
experimental obtaining of the acceleration of gravity in
the analysis of a spring through a didactic approach
Jhon Alfredo Silva Alé1
1
Departamento de Educación, Universidad de Chile, Santiago, Chile.
jhon.silva@usach.cl
Abstract. In order to meet the demands of curricular updates, this article
proposes an advance towards the design of curricular integration guidelines for
mobile learning in school mechanics. It emphasizes those objectives associated
with the processes and scientific research skills of second year of secondary
education (students between 14 and 15 years old), according to the Chilean
school organization. For the development of the guidelines, various didactic
case studies have been provided that facilitate mobile curricular integration in
the processes associated with research through collaborative dynamics centered
on the student. Specifically, the results of one of the didactic case studies
implemented in two courses during the year 2019 in schools in the Metropolitan
Region of Chile are exposed and analyzed. This study addresses introductory
phenomena to the study of Newtonian mechanics with springs through
collaborative experimentation with the use of smartphones to obtain
transversely an approximate value of the acceleration of gravity.
Keywords: Mobile learning, prescriptive curriculum, physics with
smartphones, physics teaching.
1 Introduction
In 2018, the Chilean Ministry of Education (MINEDUC in Spanish) finalizes the
implementation of the update of its Curricular Bases (CB or BC in Spanish) for
education from 7th grade to 2nd grade. In them, a new structure is proposed focused
on the achievement of Learning Objectives (LO or OA in Spanish) under a curricular
pedagogical purpose. For the case of Natural Sciences, the three main OA expected to
be developed are: Thematic Axis OA (TA or ET in Spanish), Attitudinal OA (A) and
OA for Scientific Research Skills and Processes (SRSP or HPIC in Spanish). HPIC
OAs present particularly new purposes with respect to their predecessor. One of them
requires the curricular integration of Information and Communication Technologies
(ICT) so that they favor and enhance scientific-school research experiences,
emphasizing the processes associated with data collection, treatment, processing and
Copyright c 2019 for this paper by its authors. Use permitted under Creative Commons
License Attribution 4.0 International (CC BY 4.0).
�analysis. and information for the development of scientific skills and, consequently, to
promote a degree of scientific literacy.
From the requests for curricular updates and their recent implementation, a diversity
of pedagogical needs associated with teacher accountability, curriculum coverage,
shortage of guidelines, resource scarcity, attention to diversity, etc. emerges. In
response to this, it has been decided to design a theoretical-practical model for the
mobile curricular integration of the mechanical physics of the second year of
secondary education, which will be evaluated by experts and implementation, define
the first guidelines on the processes associated with the diversification of the
Experimental research practices with smartphone use.
In particular, the results of the application of a case study on the use of mobile
technology to obtain the value of gravity acceleration will be described, which is
based on the main didactic constructs of the proposed theoretical model. In this way,
it is expected to contribute to the pedagogical needs that emerge from the curricular
updates of the physics sector in order to establish a current framework of
methodological pedagogical processes necessary to design mobile learning strategies
that enhance scientific research processes at the same time that the diversification of
experimental learning practices be promoted.
2 Background
2.1 Education and curriculum
Education, as a permanent process of construction and social preservation [6], defines
a way of living in a community that responds to a model of reality [7]. The
curriculum, on the other hand, considers a series of traditions that point to a specific
selection of content, skills and attitudes to respond to ethical purposes and for
purposes that help the educational improvement from the training process [15].
Both education and curriculum reality have been seen influenced by complex and
diverse social processes to over time, being one of the most significant and relevant
for this century that of globalization, which represents a series of restructuring
processes and how we live today [3]. One of the main social restructuring is
materializes in the field of education through the curriculum and its dimensions
Deepen the curriculum topic it means then to assume that intellectual changes, both
practical and theoretical, they are reflected in all agents of society and in their ethical
and moral philosophy. For this last reason, it would be incomplete to assume that, to
give response to the wishes, needs and curricular questions, only one type of
intellectual opinion will be considered. Is evident that a curricular analysis in what are
its three axes most influential: prescriptive, descriptive and hidden [4], requires a
thorough reflection of its dimensions emerging and regulated. For this reason, and for
the limitations programs in which this study is framed, only delve into the field of
curriculum prescription and a case of description.
2.2 Prescribed natural science curriculum
�In Chile, the General Education Law (LGE) establishes the rights and duties of
community members educational; and sets the minimum requirements that must be
demanded at each level of kindergarten, basic and mean [9]. In particular, the LGE
establishes through Curriculum Bases (BC) the main objectives of the education for
each of the disciplines and their respective axes [11]. This BC statement defines the
design curriculum based on the achievement of Learning Objectives (OA) of each of
the sectors, including the sector of natural sciences for the axes of physics, chemistry
and biology.
The OA for science declared in the BC are of three types: OA of Thematic Axes (ET);
OA of Scientific Research Skills and Processes (HPIC); and OA of Attitudes (A). ET
OAs define the contents for the teaching of each discipline of natural sciences. The
OIC of HPIC, demand rigor before the methodical processes for the development of
scholarly scientific research supported using technologies. On the other hand, both ET
OAs and HPIC OA consistently develop through ethical-moral attitudes towards
science and society through OA A. As a final goal, this type of prescriptive curricular
artifact of science establishes as a priority that the student subject, as a critical,
participatory and creative individual, understands the need to be educated in science
and the processes associated with it [11]. He stresses that the role of teachers should
encourage to the enthusiasm, amazement and satisfaction of understanding the nature
and technology [10, 11].
Finally, the curricular design described reflects the priorities of influences from
international organizations such as the Organization for Economic Cooperation and
Development (OECD), which is also based on a curriculum based on the development
of skills and therefore on skills, attitudes and knowledge.
2.3 In-depth research process learning
The HPIC OAs, aim to introduce students to the development of the skills involved
with the scientific method in a transversal way to the subjects of each level. This last
point suggests transdisciplinary support among knowledge.
The HPIC OAs are grouped into five stages, and each of them describes a scientific
research process that will allow students to achieve deep learning and also develop
critical, creative and reflective thinking, which they can use in all areas of the
lifetime. These five stages are: 1. Observe and ask questions, 2. Plan and investigate,
3. Process and analyze evidence, 4. Evaluate, 5. Communicate [11]. The HPIC OAs
present in the second-level physics BCs declare, under criteria of scientific rigor, the
use and curricular integration of Information and Communication Technologies (ICT)
to support and enhance the stages of the scientific research processes on the study of
movements, and especially for those stages of the scientific method referred to the
collection, treatment, processing and analysis of data and information for the
discovery and / or collaborative construction of scientific findings and consensus, and
their communication.
Below are the fundamentals and examples of ICT curricular integration through
mobile learning mediated by smartphones to develop scientific research processes
related to the study of mechanical physics of 2nd grade.
�3 Case study design
3.1 Mobile learning in science
The concept of Mobile Learning (ML or AM in Spanish) represents learning that
benefits and powers using mobile technology, alone or in combination with any other
type of information and communications technology (ICT), in order to facilitate
learning at any time and place [16]. Thus, the AM is established from those aspects
that are proper to these devices and that have made them look like an artifact that can
promote innovation processes in the field of educational technology. Several authors
of the last decade [1, 5, 12] have declared the importance of mobile learning to
provide solutions to problems in educational contexts. Authors have concluded that
mobile technology not only allows benefits to be provided through solutions to
educational problems [8], but also "allows the system to be broken to open teaching,
involving students in new ways and making educational experiences more
meaningful". Being consistent with the constructivist principles, the focus of mobile
learning should focus on the learning processes and not on the teaching means,
therefore, mobile learning must first and foremost be a type of learning and not a
teaching mechanism.
Thanks to the formalizations of international organizations on the AM [16] a floor
was developed to know its advantages. The main ones are: 1. The access it provides to
pedagogical resources, 2. The connectivity with other people, 3. The connectivity to
create content both inside and outside the classroom. UNESCO's conceptualization of
AM emphasizes the benefits of mobile technology, to facilitate learning. However, it
is necessary to emphasize that mobile learning has little and nothing to do with the
physical devices themselves. In the words of some leading authors [8] “mobile
learning is the experience and opportunity granted by the evolution of educational
technologies. It is any time and place enabled by instant learning, the demand for
access to a personalized world full of tools and resources that we prefer for the
creation of our own knowledge, to satisfy our curiosities, collaborating with others,
and cultivating the experiences that otherwise they would be unattainable ”(p. 31).
Thus, the AM implies adaptation, a way of being and doing culture in society,
represents styles, routines, practices, uses, experiences and opportunities. It also
embodies and facilitates the understanding of what it means to be a lifelong learner
and what it takes to thrive in today's work [8]. In the specific curricular field of
Natural Sciences (NS or CN in Spanish), the AM through curricular integration has
shown greater affinity to enhance scientific and research educational practices [2].
Specifically, mobile learning in the teaching of science, and particularly of physics,
will be understood from the descriptions of the analyzed authors [8, 16] based on the
general conceptualization of scientific literacy, to be characterized as: a type of
learning that provides opportunities and experiences to prosper critically and
constructively with the natural environment, taking advantage of the potential of
mobile technologies.
3.2 Mobile curriculum integration
The definition of curricular integration of technology is nurtured from different lines
of work and culminates as a process of articulation through the educational
curriculum to respond to the philosophical foundations of society. Outstanding
�authors [13], have developed the concept of ICT Curricular Integration emphasizing
that it allows assessing the educational possibilities of technologies in relation to the
objectives of education. Based on this, it is not ICTs that contribute to the educational
process but rather the participants of the educational act, methodologies, models and
strategies of use, which determine changes, innovation and impact on learning. [13,
14].
Mobile technologies are considered a type of ICT that in educational fields are
developed through the AM line. Thus, if the rigorous pedagogical foundations
naturally allow mobile technologies to be part of the curriculum, and link them
harmoniously with their components, then integration can be established.
3.3 CTS and CTSA approach
The BC define four central elements in the Natural Sciences curriculum, one of them
is the relationship between Science, Technology and Society (STS or CTS in Spanish)
whose purpose is oriented towards two main objectives. On the one hand, motivate
and bring students together in the study of science and, on the other, they understand
that scientific and technological applications often cause consequences in the social,
economic, political and ethical spheres [11]. With these objectives, students are
expected to be able to visualize a practical, concrete and close result of scientific
knowledge to understand the impact generated by technoscientific activity in society
and everyday life. In this way, the fact that students acquire the skills and abilities that
allow them to: Explain their environment scientifically is considered essential for the
national context; understand that scientific knowledge is contingent; apply skills to
conduct scientific research; develop personal and teamwork attitudes inherent in
scientific work; and link scientific knowledge and its applications with the demands
of society [11]. The CTS approach also has an extension within the curriculum that
considers citizen responsibility fundamental in terms of its relationship between
science, technology and society, but within an environmental framework called STSE
(CTSA in Spanish).
3.4 General description of the proposal
The development of the didactics is carried out through a sequence of 2 classes that
has the support of 3 work guides designed on the basis of specific evaluative
indicators of the ET OA No. 10 “Explain, through experimental research , the effects
that a net force has on an object, using Newton's laws and the free-body diagram.
Particularly, on the application of Hooke's law in various experimental and non-
experimental investigations where springs or other elastic materials are used ”and
HPIC OAs on“ observation of physical processes and phenomena; identification of
problems that can be solved by investigation; experimental research planning with use
of instruments, control of variables and explanation of procedures; development of a
plan measuring and recording evidence with ICT support; organization of a
collaborative work assigning responsibilities and communicating ideas effectively;
organization and presentation of data in graphics with the help of ICT; examination
and evaluation of the scientific research carried out; communication and explanation
of ideas with ICT support ”.
In class 1, two theoretical collaborative activities are developed with support from the
first two work guides. In class 2, the second part of the didactic sequence is developed
�with the help of a third work guide, a ruler and the use of the gyro sensor integrated
into the smartphone. In the last class, it is expected that, with the requested
instruments and materials, an approximate value of the gravity acceleration module
can be determined experimentally through the analysis of the physical variables in the
mass-spring system (with the smartphone as mass and simultaneous instrument ) (see
figure 1).
Fig. 1. Graphic assembly for spring-cell analysis.
The first class consists of two parts of approximately 45 minutes each. The first part is
about the analysis of four theoretical situations about spring forces for the activation
of previous learning related to Newton's principles. To address each situation,
collaborative groups of 3 to 4 students are requested to identify the physical variables
involved and thereby develop free body diagrams and explain them in their own
words. Then, propose at least one hypothesis regarding the hypothetical case of a
mass and spring system in oscillatory motion.
The second part of the first class is developed through an analysis and reaction to a
reading on bio-inspired robotics that involves the use of springs integrated into the
technology (see figure 2). It presents information with which later, in a collaborative
way, students must answer 5 development questions, these are: 1. What has caught
your attention in reading? 2. What elements or words did you not know? 3. Why do
you think robotic designs are inspired by nature? Explain with 2 arguments. 4. In
what other ways could springs contribute to society from inspired bio robotics? Find
at least 2 new examples and explain them with your words. 5. How do you think
physics could contribute to bio-inspired technological designs? 6. What ethical
challenges or problems do you think could lead to the misuse of bio-inspired robotics?
Explain with at least 2 arguments.
Fig. 2. Part of the reading for robotics analysis Bio inspired case study.
The second class is composed occupies 90 minutes, distributed in coherence with the
structure of a class.
�During the experimental activity of the second class, students are asked to perform
measurements at specific masses, times and lengths with the help of rules and the
mobile application Science Journal. In addition, it is necessary to convert the
measurements to the International System (SI) of units of measurement and record
these values in the work guides.
Then, using the relevant data and units, the calculations necessary to determine the
spring elasticity constant "k" are proposed using two different methods: Note: in both
methods, the calculations do not consider rubbing with air.
Method 1: Through a free body diagram analysis, applying Newton's laws.
(1)
To apply the first method, final and initial mass and length measurements are
necessary. For this it is necessary to use a balance that allows measuring the mass of
the smartphone together with the spring; and a ruler with a length such that it can
measure the maximum and minimum elongation of the spring.
Method 2: Through a dampened simple harmonic motion analysis, applying the
following expression derived from the circular motion analysis:
(2)
In the case of method two, there will be a simple harmonic movement that will be
slightly dampened by air as time passes. To perform mass and time measurements, a
balance and some mobile application that records the acceleration variations
graphically are required. For this case it has been used of the Google ScienceJournal
mobile application. To perform the time measurement, the smartphone must be
connected to a spring at the back (see figure 1, case 2) and have the application
configured to measure acceleration differences on the “y” axis. The procedure
consists of dropping the smartphone at a certain height without releasing the spring of
which it is attached. In this way, the smartphone will begin to oscillate with the
gyroscope sensor on, continuously until it stops by rubbing with the air. To maintain
good control of the variables, any possible friction, involuntary movements in other
axes, and hand impulses should be avoided.
After at least 5 seconds have elapsed, the smartphone will record the variations in the
acceleration of the gyroscope and graph them together with a time record, which can
be used (see figure 4).
Fig. 4. Measurements of the oscillation period of the damped simple harmonic movement,
spring-smartphone system.
�It should be mentioned that because the movement is generated in a material medium
such as air, it will become dampened, and, therefore, will lose energy after a few
seconds (see figure 5), for this reason it is considered relevant that Measurements to
the oscillation period are made in registration sections as homogeneous as possible.
Fig. 5. Analysis of the buffered measurements in the spring-smartphone system.
After the experimental determination of both elasticity constants, the second one is
used to determine the approximate value of the acceleration of gravity by replacing it
in equation (1) and using the measured length and mass values.
In addition, the discussion on the results found is promoted, opening the debate on the
consequences of rubbing with the air and the variations in the values of the
acceleration of gravity.
3.5 Learning assessment
In order to measure the development of scientific competences, the evaluation was
chosen based on the use of rubrics, checklists and group self-assessments. These
instruments have been chosen because they allow characterization with qualitative
and quantitative indicators of student performance, and thanks to their versatility they
can easily adapt to the methodological strategies that teachers deem most convenient.
The rubrics have been designed with the objective of measuring the levels of
achievement of the developments of each activity presented in the collaborative work
guide. It has been chosen to use a spectrum of 3 levels of achievement: Totally
maximum, average achieved, minimum achievement. This, to characterize the most
significant advances of each stage of the didactic sequence. The rubric allows various
measurements to be made consistent with the five stages of the research process
required in a curricular manner, to demonstrate behaviors that obey the observation of
phenomena, the questioning and hypothesis, the planning and conducting of the
research activity, the processing and analysis of data (see figures 3, 4 and 5),
evaluation and communication of conclusions. The checklist has been designed to
measure experimental manipulation and collaborative work observed during class.
The self-assessment that students do is not weighted with a grade. Its purpose is to
provide feedback to the teacher about the collaborative work performed by the
groups, also promoting criticism and self-criticism.
�4 Results and discussions
In general, the measurements of the rubrics based on evaluation indicators according
to the curricular OA, account for 80% of students with favorable results, with more
than 75% well answered on the total. On the results of the first part of the first class,
diagrams and analysis of problematic situations, it On the results of the first part of
the first class, the diagrams and the analyzes to problematic situations, it was possible
to develop most of the problems posed without difficulties, managing to apply the
Newtonian principles seen in previous classes, drawing and identifying the forces
with Diagram support, and textual application. Difficulties, managing to apply the
principles of Newton seen in previous classes, draw and identify the forces with
Diagram support, and textual application. Regarding the results to the CTSA of the
second part, critical reflections were evidenced on the applicability of the springs (see
figure 6), and the physical principles studied from bio-inspired technologies,
emphasizing the link with nature; proposals for the contribution of applied science to
technology; and the challenges and problems of abuse and misuse of such
technologies.
Fig. 6. Answers of a group of students.
Regarding mobile learning, the results of the second work guide show elements of the
development of collaborative research carried out by students, emphasizing some
difficulties with the approach to research hypotheses. However, the collection and
processing of data enhanced using smartphone sensors, their analysis and
interpretation, the rigor in the calculations, and the reflection and conclusion
processes are satisfactory in terms of high compliance achievement. It is also noted
that, within the development of the second work guide with one of the courses with 4
collaborative groups, approximate values of the gravity acceleration module have
been obtained with a percentage error with respect to the theoretical value that ranges
between 4.38% and 9.07%, as shown in table 1.
Collaborative
groups
1 9.08 7.44
2 8.92 9.07
9.81
3 10.44 6.42
4 9.38 4.38
Table. 1. Variation of the values of the experimental determination of the acceleration of
gravity with smartphone.
�5 Final consideration and future work
The didactic experience of mobile curricular integration with grafts of CTSA
approach has been favorable in terms of the above. The specific indicators of the
proposed HPIC OA have been achieved. However, the percentage errors in the
calculation of the acceleration of gravity during the guided research process carried
out by the students are still high and can unnecessarily lead to conceptual errors. For
this reason it is prudent, for future work, to establish strategies that, for this type of
experience, allow us to understand and justify the errors associated with the variables
that interfered with the phenomenon, and on the other, to take actions that allow them
to be reduced and deepen your explanation. The comments on collaborative work
have been positive. It is noted that the attitude of the students during the application
of the case study was favorable throughout the activity, showing great interest in
knowing the operation of mobile devices, and using them to generate experiences that
would allow them to learn.
References
1. Cheng, P. et. al.: 5E Mobile Inquiry Learning Approach for Enhancing Learning
Motivation and Scientific Inquiry Ability of University Students. (2016).
2. Boude, O y Barrero, I.: Diseño de estrategias de aprendizaje móvil a través de ambientes
mezclados de aprendizaje. La Sabana: Revista Sophia. (2017)
3. Giddens, A.: Un mundo desbocado, los efectos de la globalización en nuestras vidas.
México: Taurus. (1999)
4. Glatthorn, A., Boschee, F. & Whitehead, B.: Curriculum leadership. Development and
implementation. California: Sage. (2006)
5. Huang, C. et. al.: Effects of Situated Mobile Learning Approach on Learning Motivation
and Performance of EFL Students. Educational Technology & Society. (2016)
6. Jaeger, W. PAIDEIA: Los ideales de la cultura griega. Libro Primero. México: Fondo de
Cultura Económico. (2001) 10-11.
7. Lundgren, U.: Teoría del currículum y escolarización. (1992)
8. McQuiggans, S. et al.: Mobile Learning: A Handbook for Developers, Educators, and
Learners. Wiley and SAS Business Series. (2015)
9. MINEDUC.: Ley General de Educación n° 20370, LGE. (2009)
10. MINEDUC.: Estándares Orientadores para carreras de pedagogía de Educación Media.
Santiago. (2012)
11. MINEDUC.: Bases Curriculares, 7° básico a 2° medio. Chile. (2015)
12. Lagunes, C. et. al.: Prospectiva hacia el aprendizaje móvil en estudiantes universitarios.
México: Revista de Formación Universitaria. (2017).
13. Sánchez, J.: Integración Curricular de las TICs Conceptos y Modelos. Revista Enfoques
Educacionales. (2003)
14. Sánchez, J.: Bases constructivas para la integración de las TIC. Santiago: Revista enfoques
educacionales. (2004)
15. Tyler, R. Basic Principles of Curriculum and Instruction. Buenos Aires: Editorial Troquel.
(1973)
16. UNESCO.: Directrices para las políticas de Aprendizaje móvil. Paris: UNESCO. (2013).
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