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www.iop.org/journals/physed
Audiovisual physics reports:
students’ video production as a
strategy for the didactic
laboratory
Marcus Vinicius Pereira1, Susana de Souza Barros2,
Luiz Augusto C de Rezende Filho2and
Leduc Hermeto de A Fauth1,3
1Instituto Federal do Rio de Janeiro, Rio de Janeiro, Brazil
2Universidade Federal do Rio de Janeiro, Rio de Janeiro, Brazil
3Universidade Federal Fluminense, Rio de Janeiro, Brazil
E-mail: marcus.pereira@ifrj.edu.br,susana@if.ufrj.br,luizrezende@ufrj.br and
leducf@globo.com
Abstract
Constant technological advancement has facilitated access to digital cameras
and cell phones. Involving students in a video production project can work as
a motivating aspect to make them active and reflective in their learning,
intellectually engaged in a recursive process. This project was implemented
in high school level physics laboratory classes resulting in 22 videos which
are considered as audiovisual reports and analysed under two components:
theoretical and experimental. This kind of project allows the students to
spontaneously use features such as music, pictures, dramatization,
animations, etc, even when the didactic laboratory may not be the place
where aesthetic and cultural dimensions are generally developed. This could
be due to the fact that digital media are more legitimately used as cultural
tools than as teaching strategies.
Introduction
For the last 50 years there has been a tacit
agreement among science educators that experi-
mental work facilitates the understanding and con-
struction of physics concepts, encourages active
learning, motivates the interest of the students
and contributes to the development of logical
reasoning and communication, thus encouraging
enterprise, imagination and group work [1]. These
arguments led many to associate good physics
teaching practices to efficient strategies that help
implement, as much as possible, practical work at
school. It is also true that most of the research in
physics education correlates experimental practice
to improvement in students’ learning and in the
last few decades science education research work
has pointed out experimental work as a major
enhancer of physics learning, so for those reasons
labwork activities performed by the student have
been considered as a ‘magic wand’ needed to solve
the many learning difficulties known in physics
education.
44 PHYSICS EDUCATION 47(1) 0031-9120/12/010044+08$33.00 ©2012 IOP Publishing Ltd
Audiovisual physics reports
The experimental activitiesat the introductory
physics level are expected to contribute to the
development of procedural skills. Nedelsky [2]
claims that their central goal is to bring the
student to comprehend the relationships between
science and nature. This aspect is corroborated
by Kirschner’s ideas [3]: ‘it is the teacher’s job to
teach science, teach about science, and teach how
to do science’.
Lunetta, Hofstein and Clough [4] are sceptical
and, searching for evidence in the vast literature of
the field, argue that the main goals of the learning
outcomes that should arise from the physics
teaching laboratory are often not met. These goals
involve conceptual understanding and procedural
abilities (exploring arguments from the data),
knowledge of how science and scientists work,
interest and motivation, understanding of research
methods and scientific reasoning, including the
nature of science. According to Borges [5]
the effectiveness of the didactic laboratory in
promoting learning has been in question over the
years.
The European survey [6] conducted in seven
countries does not point to much improvement
in science education as related to labwork,
not even in those situations where schools
have the appropriate conditions for experimental
teaching. The report mentions that practical
activities tend to be limited to the manipulation
of objects/materials/instruments and they are
frequently performed with procedures where the
students follow precise instructions and methods
of analysis provided by programmed teacher’s
instructions. One of the recommendations is
related to the false pretence that a broad spectrum
of goals can be attained ‘at once’, objectives that
many a time may not be compatible with the type
of activity carried out. It is also worth commenting
that often teachers take for granted the ability of
the students to perform certain actions for which
they have not been instructed. Furthermore, the
survey recommends that in introductory physics
classes the tasks performed in a given laboratory
session should always be designed to deal with
only a few specific objectives [7,8].
As in many countries around the world,
laboratory classes in Brazil are seldom introduced
in regular programmes and when this is done
students follow a labwork guide that describes the
experiment to be performed, while equipment is
already laid out on the bench set up by the teacher
or tutor. Observations, results and conclusions
are already structured and so reported. Probably,
the main reason for this choice is the allocation
of a larger proportion of theory over practical
assignments within the science teaching schedule
of many schools.
This strategy gives little incentive for the
students to reflect on the conceptual aspects of
phenomena under study or to develop a deeper
understanding required to overcome the eventual
shortcomings of the experimental activity. The
planning of measurements and the exploration of
the relations between physical quantities involved
are also poorly done. Frequently, the physical
model underlying the phenomena and the possible
disagreements between predictions and results are
not shown in the conclusions, impoverishing data
interpretation and theoretical explanation.
From tradition to innovation
Currently school education can be seen in transi-
tion from traditional to innovative methodologies
and mostly the students still remain as the receivers
of information. There are also good reasons
to acknowledge the place taken by ICT (infor-
mation and communication technology) resources
because they are considered by political decision
makers as a solution for the teaching problems of
school science education. If this type of resource
can be used it is important to recognize its place
and limitations, because its role does not replace
what labwork does for sound science learning.
Because of the growth of ICT facilities and the
amount of didactic material currently offered,
there is a risk that they may replace the laboratory
as the new educational ‘magical wand’ of this
millennium.
So it could be expected that the accelerated
technological revolution may contribute to the
demands of changes in education [9]. Physics
teaching can take advantage of these resources,
since it is possible to videotape physical phe-
nomena, opening a motivational strategy for the
students who could become producers of their own
activities.
Nowadays technological gadgets are within
the reach of the common citizen, thus making
it possible to introduce independent audiovisual
production as a new strategy. From this
perspective the school can be thought of as an
January 2012 PHYSICS EDUCATION 45
MVPereiraet al
irradiating pole of knowledge and the teacher as
the mediator, leading the students to externalize
their creative thinking while producing a video.
This is a new way of thinking and doing, to
make the students ‘discover new possibilities of
expression, performing group experiences in a
collective creation effort’[10].
This article proposes to discuss the role of
video production by the students as an approach to
the physics laboratory which has proven efficient
when implemented in a Brazilian high school.
Students’ video production project
The production of a video independently made
by the students brings a fresh perspective to
the practical work they experience in school.
The strategy allows the implementation of objec-
tives such as intellectual (academic), procedural
(trying concepts to realize physical quantities)
and cognitive–affective (motivating students to
undergo a process of metacognition throughout the
whole experiment).
The possibility of innovation changes the
rhythm of a physics classroom, modifying the
merely one way communication and introducing
activities planned, organized and performed by
the students. When using a video camera
they can externalize creative thoughts as well
as warrant the pedagogical potential, because it
allows visualization of physical situations related
to conceptual physical models, and so bring about
the discovery of new possibilities of expression
while experiencing exchanges while working in a
group in an effort of collective creation [10,11].
A strategy to develop laboratory activities
based on students’ video production of physics
experiments can provide a feasible substitute
for the traditional didactic laboratory [12].
When involved in the project the pupil engages
in different activities, both instrumental and
cognitive: hands on and minds on. They are
responsible for all the steps to mount and test the
experiment, which means involvement along the
complete line of events necessary for the task: to
identify and research key concepts, principles and
laws that allow them to understand and create the
experimental situation which will be tested and
modified as required.
For the development of their project the
students can either use the equipment available in
the school laboratory or create their own setup. It
is also essential to present a written outline of the
general ideas and processes to establish a timetable
for the activities to guide the production. This
organization gives the students a flexible schedule
to develop independent work as well as to allow
the feedback that characterizes this kind of task.
It is important that students realize the
assignment is not an amusing game, but it has
the intention of developing a structured piece of
work. Video attributes are anticipated in order
to structure the intellectual component of the
enterprise, so the following points are made clear
from the start. The video produced should:
•pursue a set of a few main objectives;
•allow concept comprehension;
•be conceptually autonomous;
•present a logical sequence;
•integrate oral, written and visual languages
(clarity of communication);
•be no longer than 4 min in length.
Several objectives define the project features:
•cognitive: the project may enhance (induce)
students’ cognitive processes for the learning
of physics concepts;
•motivational–technological: to immerse the
students actively in their learning process and
to use technological resources (digital video
cameras and other devices to record and
capture images, audio and software for
editing the video);
•recursive–reflexive: the project is developed
in short related steps, which are not
necessarily linear, allowing ‘round trips’
according to the tasks.
Project development
The complete implementation of this project takes
about four months of school time, resulting in a
video produced in groups up to five students each.
To begin with, written material with back-
ground information, objectives, video characteris-
tics, timing/schedule and criteria of assessment is
presented. Each group selects a topic and begins
research of physical concepts and the choice of
practical activities. Next, the groups plan, mount
the set-up and test the experimental situation.
It is important to draw attention to the
importance of guidance in order to produce a video
as an audiovisual report. At this point they produce
46 PHYSICS EDUCATION January 2012
Audiovisual physics reports
video production
selection of the topic
Figure 1. Video production flowchart.
initial orientation
brainstorm
discussion and inquiry
selection of information
concept mapping
testing experiments
storyboard critical reading
screenplay
filming and editing
screenplay and review selection and information
proposition mapping
new ideas
self assessment
video, exhibition and evaluation
a simplified storyboard, which is discussed with
the teacher, to reflect the exploration of the
phenomenon. The subsequent screenplay guides
the steps of video production and editing. Once
the video is produced it will be exhibited to the
whole classroom and evaluations can be applied.
Figure 1illustrates the project development,
explicitly showing its feedback features.
Project implementation results
This project was implemented in five classes,
totalling around 100 students of a technical public
high school in Rio de Janeiro city. Regular
laboratory classes in this school are frequently
taught following traditional labwork guidelines.
Figure 2shows representative images of the
physics phenomena treated in the 22 videos. All
videos were edited non-linearly and have captions
as well as, in some cases, pictures and animations.
They also present commentary (most of them as
voice-over) and soundtrack juxtaposed with the
images.
In this article each video is considered as
an audiovisual report. For the sake of analysis
the videos were divided in two components:
theoretical components (TC) and experimental
components (EC).
TC represents the objectives proposed, phys-
ical concepts, laws, principles and general ideas,
needed for the development of the experiment.
EC involves mounting and testing the experi-
ment, filming scenes and editing, where students
are responsible for developing procedures, gath-
ering and analysing data, discussing results and
presenting conclusions. Initial and final credits are
not included in the TC and/or EC.
Table 1shows the title assigned by the authors
(and the total length in minutes:seconds), place
of production (PP)—school laboratory (SL) and/or
home laboratory (HL)—and the discrimination
between time spent developing TC and EC.
January 2012 PHYSICS EDUCATION 47
MVPereiraet al
Figure 2. Videos produced.
The videos were filmed in different set-ups:
14 were produced in the school laboratory, four
of them in a home set laboratory and four were
recorded using both places. It is worth noticing
that two videos produced in the school laboratory
made use of dramatization resources: I and V.
In discriminating theoretical and experimental
components, it was found that three videos, J,
Q and R, did not fit these criteria, possibly due
to the fact that they are strongly focused on the
instrumental aspect of the experiment.
Most of the videos (14 out of 22) show
predominance of the EC over the TC. The four
videos which clearly develop the TC over the
EC are associated to physical principles and laws
(collisions and light refraction: B, C, U and
V). From a cognitive perspective, this can be
interpreted by the fact that these concepts are
easier to understand and express theoretically
rather than presented practically.
The audiovisual report allows a flexible struc-
ture when compared to the written report, as shown
48 PHYSICS EDUCATION January 2012
Audiovisual physics reports
Table 1. Classification of videos according to place of production (PP)—school laboratory (SL) and/or home
laboratory (HL)—, theoretical (TC) and experimental (EC) components.
Video Title (and length in min:s) PP
TC
min:s
EC
min:s
A Resonance effect in pendulums (4:50) HL +SL 0:24 3:32
B Understanding physics: light refraction (2:45) SL 1:27 0:37
C Collisions: energy conservation (4:30) SL 2:55 1:05
D Ohmic and non-ohmic resistance (5:00) SL 0:40 3:47
E Physics aquarium (2:20) SL 0:08 1:49
F Pascal’s principle (4:15) SL 1:05 3:02
G Buoyancy (6:15) SL 1:10 4:43
H Centripetal and tension forces (3:30) SL 0:30 2:30
I Electromagnetic motor (3:40) HL +SL 1:41 1:33
J Chemie boat (2:25) HL 2:25
K Horizontal motion and gravity (4:50) HL 0:43 3:26
L Direct current motor (3:20) SL 0:52 2:13
M Heat propagation: convection currents (3:20) HL +SL 1:00 2:41
N Electromagnetic induction: Faraday’s law (5:00) SL 1:35 2:55
O Friction force (4:26) SL 0:40 3:20
P Mechanics: energy conservation (2:08) SL 0:22 1:26
Q Magnetic brake: Foucault’s currents (3:25) SL 3:25
R Magic diver (4:55) HL 4:55
S Liquid pressure (3:02) HL 1:00 1:48
T Electric motor (3:59) SL 1:10 2:30
U The case of the bent straw (5:27) HL +SL 3:10 1:03
V Light refraction (4:07) SL 2:30 0:45
in the following examples: (i) L presents the
experiment after explaining the theory to discuss
the results; (ii) U builds up a relationship between
the experimental activity and its daily application;
(iii) Q associates the activity to a problem situa-
tion. Another piece of evidence of this flexible
structure is observed in four videos where the con-
clusions are discussed along with the performance
of the experiment itself: E, F, M and N.
It is worth noting that resources related to
the aesthetic and cultural dimensions (music,
dramatization, picture/image, animation, etc)
enrich the videos and are spontaneously used
in an audiovisual report, indicating that the
students regard them as necessary to better express
themselves. This can be understood because
audiovisual resources are deeply rooted instudents
as a cultural tool rather than as a teaching strategy,
even when videos are produced as a physics
laboratory task. It can be pointed out, as a
positive aspect, that some videos exhibit elements
of humour, an emotion that is rarely shown in
relation to physics, seen by many students as the
‘bogeyman’. Table 2highlights these trends.
Most of the videos produced illustrate corre-
lations between the physical quantities involved in
the phenomena: B, D, E, F, G, I, K, L and N.
Table 2. Frequency (N) of resources used.
Resource N
Music 14
Dramatization 3
Commentary 19
Caption/text 19
Initial and/or final credits 22
Picture/photo/image 15
Animation/simulation/movies 5
Editing effects 20
Video N presents an important feature of the
magnetic induction phenomenon: the effect on the
ammeter of the speed of a magnet when introduced
in a coil is studied, but there is no date registered,
just the motion of the needle is shown as evidence.
Video D makes a formal study of Ohm’s law,
showing tables and a graphical representation of
the data gathered experimentally: current versus
voltage for two different circuit components, a
resistor and a lamp. The analysis allows the
students to conclude from experimental evidence
that the electrical resistance is dependent on
temperature.
Correlations without explicit values of phys-
ical quantities involved are made in videos I
January 2012 PHYSICS EDUCATION 49
MVPereiraet al
and L—both dealing with the same system, an
electromagnetic motor. These videos control
physical quantities—radius, number of turns and
tension applied—that modify the magnetic field
generated in a wire loop and correlate them with
the speed of rotation of the coil (motor shaft). The
measurement of the wire loop speed is mentioned
verbally instead of obtaining it from the frame to
frame frequency of the video.
Archimedes’ principle is the issue of video G
which depicts the control of physical quantities
and their correlations, discussing relevant and
irrelevant physical quantities. In this video,
students make use of the same experimental design
in three different situations: a metal body attached
to a dynamometer that measures its weight when
suspended in air (reading 1) and its apparent
weight when fully immersed in a liquid (reading
2). The determination of buoyancy, the difference
between readings, is correlated with the density of
the liquid and the volume of the immersed body
(relevant quantities) and also the density of the
body (irrelevant quantity).
Some videos, A, H, J and M, mix up
description and explanation, as well as not making
correlations between physical quantities relevant
to the phenomena.
Table 3provides the links to some of the
videos produced in this project.
Conclusions
One of the advantages of this strategy compared
to the traditional laboratory is the responsibility
assumed by the students. This is because making
the video, which will be watched by others,
requires the students’ intellectual engagement
through research on the subject, comprehension
of key concepts and creation of an appropriate
experimental situation, which will be tested,
modified and checked as many times as necessary.
This feature reflects the operational necessity
to deal with phenomena expressed visually
that differentiates the video production labwork
from the experimental activities conducted in a
laboratory that, in general, it is an ordered process
required by the programmed report carried out
with a very low level of recursion. The technique
draws in skills such as handling equipment,
gathering, recording and analysing data, all of
Table 3. Audiovisual reports on Youtube.
Video Youtube link
Byoutube.com/watch?v=Z0jH0THNZAg
Cyoutube.com/watch?v=3bxbKozNvA0
Dyoutube.com/watch?v=NSKg23gM41s
Eyoutube.com/watch?v=4GIvQK4cdgI
Gyoutube.com/watch?v=LJmhDuDtGHQ
Qyoutube.com/watch?v=SUuqvPK2fHs
Nyoutube.com/watch?v=8usBJnCZW9s
Syoutube.com/watch?v=4cygKYplrl4
Tyoutube.com/watch?v=6uMMMJldxBE
which lead to a concrete product—the audiovisual
report.
The audiovisual report shows intrinsic char-
acteristics which do not exactly match with the
components of the typical written report (theory,
objectives, equipment, etc), either due to the
production process or because of the students’
expression in audiovisual language. This fact
is evidenced by the free-form chosen by the
students to structure the physical phenomena,
making free use of resources, not requested in
the guidelines, which characterize the audiovisual
format (narration, caption, animation, images,
etc) to explain concepts, laws and/or physical
principles while developing and manipulating the
experiment.
Another advantage of the audiovisual over
the written report is the fact that it does not
require sequenced guidelines. In such a way it
can be expected that this type of project may
enhance imagination and creativity as well as
having implicit cognitive aspects.
Received 3 June 2011, in final form 1 July 2011
doi:10.1088/0031-9120/47/1/44
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50 PHYSICS EDUCATION January 2012
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Marcus Vinicius Pereira teaches at the
Education, Science and Technology
Institute of Rio de Janeiro (IFRJ). He
majored in physics and is a doctoral
student in science and health education.
His main interest is information,
communication and technology in
science education, specifically video
production and video reception.
Susana de Souza Barros is a
graduate-level physics teacher at the
Federal University of Rio de Janeiro
(UFRJ). She researches physics strategies
for pre-service and in-service physics
teacher training and is also involved in
studying the efficiency of classroom
strategies.
Luiz Augusto Coimbra de Rezende
Filho teaches in the Science and Health
Education Graduate Program at UFRJ.
He majored in media studies and cinema
and does research in education and
communication. His interests are
documentary film theory, educational
video and cinema, media reception,
audiovisual archives, and science and
health education.
Leduc Hermeto de Almeida Fauth is a
physics teacher and also an electronics
technician and held a scholarship at IFRJ
(2009–11). His interests are the
production of teaching materials, video
production and low-cost materials for
physics teaching.
January 2012 PHYSICS EDUCATION 51