International Journal of Interactive Mobile Technologies (iJIM) – eISSN: 1865-7923 – Vol. 15, No. 14, 2021


Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

How Effectively Can Students’ Personal Smartphones be 

Used as Tools in Physics Labs? 

https://doi.org/10.3991/ijim.v15i14.22375 

Serafeim Tsoukos 
2nd Experimental Junior High School, Athens, Greece 

Panagiotis Lazos 
National and Kapodistrian University, Athens, Greece 

4th Laboratory Center of Natural Sciences, Athens, Greece 

Pavlos Tzamalis 
Agricultural University, Athens, Greece 

Alexandros Kateris 
2nd Experimental Lyceum, Athens, Greece 

Athanasios Velentzas () 

National Technical University, Athens, Greece 
avelentz@gmail.com 

Abstract—This study seeks to answer the question of how effectively stu-

dents can use their smartphones as tools for measuring and processing data 

when they perform physics experiments. The research was conducted in a local 

secondary school in Athens, Greece. The sample consisted of fifty-two 16-year-

old students (10th grade), who were divided into 26 pairs and asked to perform 

an experiment using their smartphones for measuring, processing and saving 

data, and then to email the data file to the researchers. During the implementa-

tion, each pair completed the steps on a worksheet. Two researchers monitored 

each pair individually, and recorded scores and comments on evaluation sheets. 

The worksheets, the evaluation sheets, and the experimental data emailed by 

each pair constituted the data of the present study. The findings of the study 

show that the integration of students’ smart mobile devices in the performance 

of physics experiments in the classroom or in the school lab is possible without 

posing particular problems. However, this integration presupposes the proper 

planning by the teacher and the dedication of appropriate time both for the 

preparation of students for the activity, and for the installation of the necessary 

applications in the devices. 

Keywords—Smartphone Sensors; School Lab; BYOD; Physics Experiments 

iJIM ‒ Vol. 15, No. 14, 2021 55

https://doi.org/10.3991/ijim.v15i14.22375
mailto:avelentz@gmail.com


Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

1 Introduction 

The fact that as early as 2014 in some of the most developed Western countries, 

such as the United States, Germany, the United Kingdom and Japan, the number of 

smartphones exceeded the number of desktop PC’s [1] vividly shows the degree of 

penetration of these types of devices in our everyday lives. It is reasonable to assume 

that since 2014, many more countries have been added to this group. The continuous 

reduction in the cost of this kind of technology convinces us that sooner or later in 

most countries smartphones will be used by almost everyone. Combining this devel-

opment with the fact that mobile devices are widespread especially among younger 

people, the transition from the field of education that is usually called “electronic 

learning”, or “e-learning”, to the new era of “mobile learning” or “m-learning”, be-

comes inevitable [2]. The assumption that such a transition is actually taking place is 

also documented by the increase in the number of articles in the field of m-learning 

worldwide. For example, Hwang and Tsai [3] found that the number of papers pub-

lished in the field of m-learning from 2005 to 2010 was four times higher than the 

corresponding number for the years 2001 to 2005, and this increase continues [4]. 

Although there is an intense and evolving debate in the international literature both 

on the definition of m-learning [5] and on the devices and applications that can be 

included in this category of education [6] [7] [8], in the present work we will adhere 

to the minimum common position that has been shaped by these discussions: Thus, 

there gradually seems to be an increasing agreement among different researchers that 

the field of m-learning includes devices which can be easily transported, due to their 

small size and weight, while having the capability of wireless connection with the 

World Wide Web (WWW). Typical devices that meet such criteria are mobile phones 

(MPs) and tablets. 

Several papers show that, despite some problems, such as distraction or small key-

boards [9], learning is aided by mobile phones, as long as appropriate rules have been 

posed [10]. In addition to the general advantages of m-learning identified by different 

researchers [11], such as learning without local and temporal limitations, connectivity 

with the WWW, ease of data exchange in different formats such as images, videos, 

texts, and so on, m-learning devices also have an additional advantage as far as sci-

ence education in general is concerned [4] [12], and especially in physics courses [13] 

[14] and in the physics laboratory classes [15]. More specifically, we are referring to 

the exploitation of the capabilities provided by the various built-in sensors that all 

these mobile devices have, which are used to serve some of their basic functions. For 

example, the acceleration sensor is used to change the orientation of the screen every 

time a smartphone is rotated. Using appropriate applications, data can be extracted 

from these sensors, which data can be immediately visualized with graphs on the 

mobile device and often processed in order to obtain some preliminary results. The 

multiplicity of the sensors in the modern MPs, such as light and sound sensor, gyro-

scope, magnetic sensor, and others, allow the conducting of experiments in different 

areas of physics, e.g. mechanics [16] [17], optics and acoustics [18] [19], heat and 

thermodynamics [20], and even in modern physics [21]. In addition, the easy, wireless 

and seamless connectivity of these devices to the WWW can help teachers share the 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

data with their students, create teams of students working collaboratively, and in gen-

eral interact directly with them. The review of the relevant literature [15] highlights 

both the variety of the use of MPs and tablets in the school, and the development of 

the educational research in the corresponding field: Thus, the integration of m-

learning into the educational process and the training of teachers in this field are now 

considered necessary [22]. This specific use of mobile devices and the possibilities it 

offers to students for conducting experiments when they do not have access to the 

appropriate laboratory equipment seems to have been a solution that many teachers 

resorted to during the recent COVID-19 pandemic [23]. 

However, in order to advance learning through the use of mobile devices, one of 

the first and most basic problems that needs to be resolved is how to integrate m-

learning into education [1] in general, and into the science school lab in particular. 

Among the different proposals that have been put forward, one is summarised with 

the phrase “Bring Your Own Devices” (BYOD). It is a strategy that initially started in 

the business sector and was then extended to other areas, including education [24] 

[25]. It is worth remembering that an alternative idea, namely providing inexpensive 

personal computers to students in developing countries, was proposed by N. Negro-

ponte in 2000, and began to be implemented in 2005 (http://one.laptop.org/). The 

BYOD proposal has significant advantages for an educational system, including the 

fact that students are already familiar with the use of their own devices, and that 

schools are not financially burdened by the purchase of specialized laboratory devices 

that usually come at a high price, although there are still other open problems with 

BYOD that need to be overcome [26] [27]. On the other hand, of course, it is ex-

pected that the plethora of all these different devices that students bring to the class-

room, and which the teacher must coordinate during a laboratory course, may pose 

significant problems, an issue that was examined by Kateris et al. [28]. The specific 

way in which students’ mobile devices students are integrated into teaching must 

therefore be studied in real-world conditions to detect any problems that may arise.  

In this paper, we focus our attention on the practicality for taking measurements 

using the MP sensors of the devices that students bring to the laboratory. The prob-

lems that are expected to arise may be due, on the one hand, to the differences be-

tween students’ devices attributable to different manufacturers, models, and software 

and, on the other hand, to the ability of students to use the devices and the necessary 

software when implementing the instructions of a worksheet. As far as regards the 

first type of problems, i.e., problems due to device differences, previous research [28] 

has shown that the teacher who implements the BYOD model will not encounter 

particularly significant problems due to the plethora of students’ different mobile 

devices. As for the second kind of problems, i.e., student’s ability to correctly use the 

devices for measurement, there are no surveys focusing on the ability of students to 

use the devices in a demanding sequence of experimental procedures in the context of 

a physics laboratory. What is unique in this study is an attempt to provide information 

on this issue.  

There have been surveys focusing on students’ working cooperatively and the en-

hancement of their interest/ motivation [29] [30], reports of potential benefits from the 

use of MPs in teaching and learning [31], as well as many suggestions for educational 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

exploitation of the sensors of a MP for the presentation of physics experiments (e.g. 

[16] [19] [32] [33]). The present study was designed to identify the technical difficul-

ties that students would encounter when conducting an experiment using their own 

MPs in the school lab. A controlled environment was therefore chosen, where two 

pairs of students successively performed the same experiment (about which they had 

previously been instructed) in front of two of the researchers. The researchers moni-

tored each pair’s performance, and assessed them as they were carrying out the vari-

ous steps to successfully complete the experiment. Thus, the main question that the 

present research is trying to answer is “To what degree are students able to use their 

MPs to take measurements and process data in the school science laboratory when 

following the instructions on a worksheet?”  

2 Materials and Methods 

2.1 The selection of the experiment 

The selected experiment concerned the measurement of the acceleration of a body 

(a rectangular wooden parallelepiped) sliding on an inclined plane (the surface of a 

desk), and the calculation of the coefficient of kinetic friction between the two surfac-

es. One end of the desk was raised, creating an inclined plane of inclination angle φ. 

Then, students attached their MP on the rectangular wooden parallelepiped and the 

resultant body (parallelepiped + MP) was allowed to slide from the top to the bottom 

of the inclined plane. The measurement of the acceleration (a), as well as the value of 

the angle φ, was accomplished using the accelerometer of the smartphone. The coeffi-

cient of kinetic friction can be calculated from the formula: 

 𝜇 =
𝑔∙𝑠𝑖𝑛𝜑−𝛼

𝑔∙𝑐𝑜𝑠𝜑
 (1) 

This specific experiment was selected because it had been tested in a relevant study 

and it was found that the measured values, from a variety of devices, did not have 

statistically significant differences [28]. Another criterion for selecting this particular 

experiment was the fact that not only did the participating students have to make a 

simple measurement, they also had to follow instructions for a variety of procedures. 

The specific procedures and steps are described in detail in the section “The Sample 

and Preparation” but in brief, students were required to install multiple applications 

on their MPs, learn how to handle them, obtain measurements of the angle of inclina-

tion and acceleration, adjust the settings on their MPs according to the specific task, 

record, save, and send data in a specific format, and perform appropriate calculations.  

2.2 The worksheet and the pilot implementation 

To ensure better observation of students’ performance and obtain a more detailed 

evaluation of possible technical difficulties they might encounter, it was decided that 

the experiment should be performed by as small groups of students as possible, i.e., 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

by two students working in a pair. Then, a worksheet with nine steps was created, as 

described below in the “Findings–Results” section. The worksheet was tested with 

three groups of students to check for possible problems, mainly relating to the stu-

dents’ understanding of the given instructions. After the identification of some ambi-

guities and some points difficult for students to understand, improvements were made, 

and the final form of the worksheet was prepared. One of the findings of the pilot 

research that is worth noting was the problem students had in interpreting the acceler-

ation time diagram. In particular, they faced great difficulty in recognizing the area of 

the graph on the MP screen where the body was sliding across the inclined plane with 

constant acceleration. This difficulty may be attributable to the fact that the graph of 

the actual experiment differs significantly from the theoretical graphs that the students 

are familiar with. This problem was taken into consideration during the actual imple-

mentation, as mentioned below in the section “Implementation and Evaluation”. 

2.3 The sample and the preparation 

The sample consisted of fifty-two 16-year-old 10th grade physics students attend-

ing a secondary school in Athens, who were organized into 26 pairs. It is important to 

note that all students were informed about the whole procedure before the implemen-

tation of the experiment during a one-hour briefing session.  

Specifically, during the briefing session, the students:  

• Downloaded and installed the necessary apps on their MPs: “Bubble level” (Gam-

ma Play/Android – Lemondo entertainment/iOS) and the “Sparkvue” (Pasco) app 

for all operating systems.  

• Became familiar with the “Bubble level” app so that they could measure the angle 

of the inclined plane. 

• Became familiar with the “Sparkvue” app so that they would be able to complete 

the relevant steps in the experiment. 

• Became familiar with the calculator app of their MP so that they could calculate 

the sine and cosine of an angle. 

2.4 Implementation and evaluation 

Each pair of students performed the experiment “individually” (i.e., one pair in the 

lab at a time) so that the researchers could record their performance and any possible 

difficulties in detail. A worksheet with written instructions was given to each pair, and 

they had to follow the steps to complete the experiment. Each pair used an MP be-

longing to one of them, in which the necessary apps had been installed during the pre-

implementation briefing. The performance of the experiment required the participa-

tion of at least two students, without it being possible for both of them to perform all 

the operations on the MP at the same time. For example, one of the students released 

the body from the top of the inclined plane, and the other had to catch it at the end of 

its track. However, they were permitted to discuss how to adjust the settings on the 

MP and how to process the data. Therefore, the evaluation focused on the collabora-

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

tive result of the pair, and not on each of them individually, although observations 

about cooperation and individual difficulties were recorded. It should be noted that in 

the reality of the classroom or the laboratory, the experiments are performed by stu-

dents working in pairs or larger groups.  

In order to achieve a more objective and transparent evaluation, two researchers, 

each having a preliminary evaluation sheet, simultaneously monitored the successive 

pairs of the students performing the experiment and recorded scores and comments. 

These preliminary evaluation sheets contained the same steps as did the students’ 

worksheets. When each pair of students had completed the experiment and left the 

lab, the researchers compared their preliminary evaluations, discussing their com-

ments and their points of agreement or disagreement in order to arrive at a final eval-

uation, which was recorded on a separate sheet. The students’ worksheets, the final 

evaluation sheets, and the data emailed by each pair of students to the researchers 

constituted the data of this research.  

The present study explores the students’ ability to use their MPs for performing 

experiments in the school lab and does not focus on conceptual difficulties. For ex-

ample, as had also been the case during the pilot implementation, students had diffi-

culty interpreting the acceleration time diagram. To overcome this, the researchers 

intervened and provided the necessary explanations. Concerning the students’ ability 

to use the devices to follow the instructions on the worksheet, the researchers assessed 

students’ performance on the evaluation sheet based on a scale from 1 to 4, as well as 

by making notes or comments about their observations. The assessment score of 1 

corresponds to the cases where students were for some reason unable to perform the 

step by themselves, and the intervention of the researchers was necessary in order for 

the pair of students to proceed to the next step. The score of 4 corresponds to the cases 

in which the students effectively and efficiently performed the experiment entirely on 

their own. The scores of 2 and 3 refer to cases where students required some degree of 

help or a reminder. Specifically, the following ten key points of the experiment were 

assessed:  

1. Measurement of the angle of the inclined plane 

2. Starting a new experiment 

3. Setting of the measurement rate 

4. Setting the precision of the measurements 

5. Zeroing out the initial acceleration 

6. Starting data recording 

7. Storing/saving of data 

8. Calculating the average value of the acceleration 

9. Storing/saving of the changes to the graph 

10. Using of the MP’s calculator 

These points were incorporated into a series of nine numbered procedural steps on 

the students’ worksheets, steps which are described in the “Findings-Results” section 

below.  

It is worth noting that a meta-analysis of both the completed student worksheets 

(i.e., a check of students’ calculations) and the files of the “Sparkvue” app emailed by 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

the students were taken into consideration for the final evaluation. For example, the 

students had been asked to zero out the acceleration sensor when the body was placed 

on the inclined plane. The meta-analysis of the data, and particularly the review of the 

acceleration time graph, clearly showed whether (i) the students had correctly set the 

acceleration to zero with the body on the inclined plane, or (ii) they had not done it at 

all, or (iii) they had incorrectly done it with the MP on the horizontal plane (table). 

Also, from the same graph, we were able to identify whether the students had chosen 

the correct “Range of Interest” in order to calculate the average value of the accelera-

tion. 

3 Findings-Results 

The following are the findings for each step of the experiment procedure included 

on the worksheet. An analysis of the scores is shown in Table 1. 

Table 1.  Scores of selected worksheet steps 

 
% of  

pairs rated 1 

% of 

pairs rated 2 

% of  

pairs rated 3 

% of  

pairs rated 4 

Step 3: 

Calculation of angle φ 

 

0% 

 

0% 

 

15% 

 

85% 

Step 4:     

Sub-step 4.1: 

Start a new experiment 

 

8% 

 

8% 

 

8% 

 

76% 

Sub-step 4.2: 

Set measurement rate to 1kHz 

 

8% 

 

4% 

 

4% 

 

85% 

Sub-step 4.3: 

Precision 0.01 m/s2 

 

4% 

 

15% 

 

23% 

 

58% 

Sub-step 4.4: 
Zero out the sensor 

 
15% 

 
4% 

 
8% 

 
73% 

Sub-step 4.5: 
Start Recording 

 
4% 

 
12% 

 
15% 

 
69% 

Step 5: 

Data storage 

 

4% 

 

0% 

 

4% 

 

92% 

Step 7: 

Find the mean acceleration value 

 

12% 

 

15% 

 

38% 

 

35% 

Step 8: 

Save changes 

 

0% 

 

0% 

 

0% 

 

100% 

Step 9: 

Calculations 

 

0% 

 

4% 

 

23% 

 

73% 

3.1 Steps 1 and 2: Preparation 

As mentioned above, the appropriate applications had been downloaded to the stu-

dents’ MPs during the pre-implementation briefing. In steps 1 and 2, each pair of 

students initially had to decide which of their two MPs they would use, and then 

mount it onto the wooden parallelepiped, provided by the researchers, to create the 

body that would slide down the inclined plane. The procedures involved in these steps 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

do not concern the major questions of our survey, and therefore no grades were as-

signed, or corresponding findings recorded. 

3.2 Step 3: Measurement of angle φ 

Students first had to launch the “Bubble Level” application on their MPs and place 

the body they had created in Steps 1 and 2 at the top of the inclined plane (Figure 1). 

Then, they had to hold it steady in order to find the angle of inclination φ, using the 

above-mentioned application which measures the inclination of the screen level of the 

MP relative to the horizontal plane (Figure 2). When the body is placed on the in-

clined plane, with the y axis across the inclined plane, then the angle of inclination of 

the y axis of the MP is the one to be recorded, while the angle of inclination of the x 

axis is almost zero. The angle of inclination of each axis is shown as a positive or 

negative value by the “Bubble Level” app, depending on the orientation of the MP 

relative to the plane. Clearly, the absolute value must be recorded in the worksheets. 

All the above points had been explained to the students during the pre-implementation 

briefing.  

 

Fig. 1. The experimental setup 

Findings: Twenty-two of the twenty-six student pairs (85%) received a grade of 4, 

and the remaining four pairs a grade of 3. Students who received a grade of 3 had 

some difficulty completing the worksheet on their own and had resorted to asking the 

researchers for help in choosing the appropriate angle of inclination or recording the 

negative sign of the angle of inclination.  

It is worth mentioning that one pair of students thought that the height at which the 

MP is placed plays a role in measuring the angle of inclination of the plane, and that 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

the appropriate position for determining the measurement is at the lowest point of the 

inclined level (i.e., it’s base). This finding, along with others presented below, demon-

strates some conceptual difficulties that students face and which need further investi-

gation, but are not the subject of this research. 

 

Fig. 2. Left, the MP’s x, y and z axes. Right, the inclination angles of the  

MP’s x and y axes as measured with the “Bubble level” app 

3.3 Step 4 

In this crucial step, students were asked to complete tasks by using certain options 

of the “Sparkvue” app, which required their following a procedure with five sub-

steps: 

Sub-step 4.1: Start a new experiment: In this sub-step, students were asked to 

start a new experiment to record the total (net) acceleration with a graph, using the 

“Sparkvue” application. This application enables the recording of the acceleration in 

each of the three axes (x, y, and z), as well as the total acceleration of the body as a 

function of time. 

Findings: A few pairs of students did not remember the procedure which had been 

presented to them earlier during the pre-implementation briefing, requiring an inter-

vention from the researchers in order for them to proceed with the execution of the 

experiment. Specifically, 8% of the pairs received a grade of 1 (i.e., they required 

critical help), 8% received a grade of 2 (i.e., a reminder/ some help required), 8% 

received a grade of 3 (i.e., simple confirmation of students’ questions), and finally 

76% of the pairs received a grade of 4 (i.e., no help required).  

Sub-step 4.2: Set measurement rate to 1 kHz: For the purposes of this sub-step 

of the experiment, students had to set the measurement rate on the “Sparkvue” appli-

cation equal to 1 kHz.  

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

Findings: It is worth noting that the pairs that had difficulties in sub-step 4.2 also 

encountered difficulties in step 4.1, leading to similar scores. Specifically, 84% of the 

pairs received a grade of 4, 4% received a grade of 3, 4% a grade of 2, and finally 8% 

of the pairs a grade of 1. 

Sub-Step 4.3: Set the precision of net acceleration to 0.01 m/s2: Students had to 

use the “Sparkvue” application to set the precision of acceleration to two decimal 

places. 

Findings: Fifteen student pairs (58%) received a grade of 4, while six pairs (23%) 

received a grade of 3. The latter grade was assigned because three of the six pairs had 

initially inadvertently skipped this sub-step, but were able to do it without help when 

the researcher pointed out their omission, while the other three pairs asked for confir-

mation to perform the task. Five pairs (19%) had difficulty realizing that the required 

precision in the measurement of acceleration is achieved by setting the number of 

decimal places to 2, even though this procedure had been demonstrated and practiced 

during the pre-implementation briefing. Of these five pairs, four received a grade of 2 

(i.e., a reminder was needed), and one pair received a grade of 1 (i.e., the setting on 

the “Sparkvue” application had to be adjusted by the researcher). 

Sub-step 4.4: Zeroing out the acceleration sensor: In this sub-step, the students 

were asked to “zero out”, i.e. reset, the acceleration sensor when the body was at rest. 

If there is no zeroing out, the sensor also measures the acceleration of gravity. 

Findings: The crucial point during the execution of this sub-step was for students 

to zero out the acceleration sensor after the body had been placed on the inclined 

plane and was kept at rest, a requirement which had been pointed out to students dur-

ing the pre-implementation briefing. One pair of students (4%) did not zero out and 

were helped by the researchers (graded with a 2), while two pairs (8%) of students 

asked for confirmation that they had to zero out when the body was on the inclined 

plane (graded with a 3). The processing of the student graphs sent to the researchers 

showed that 15% of the groups had zeroed out when the body was on a horizontal 

plane (table) and continued the process, resulting in a systematic error in measuring 

the mean value of acceleration (graded with a 1). The remaining 73% of the pairs 

received the grade of 4. 

Sub-step 4.5: Start recording: Students were asked to first start recording the ac-

celeration readings using the option provided by the application, and then to release 

the body in order to move freely on the inclined plane. 

Findings: During the experiment, three pairs of students (12%) did not remember 

to start the recording, and were helped by the researchers (receiving a grade of 2), 

four pairs of students (15%) asked for confirmation that they should start the record-

ing (graded with a 3), while the students in one pair let the body move without start-

ing the recording and, after the end of the descent of the body, they realized that the 

acceleration values had not been recorded (graded with a 1), and were allowed to 

repeat the experiment. The remaining 18 pairs (69%) received the grade of 4. 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

3.4 Step 5: Storage of data 

In this step, the students were asked to save the measurements as well as the graph 

of the total (net) acceleration over time in a new file. The “Sparkvue” application uses 

a specific file format with the extension “.spklab”. 

Findings: This step was designed so as to provide the researchers with a complete 

picture of all the data students had obtained during the experimental process in order 

to evaluate them. During the experiment, one pair of students asked if they had to 

save the data, receiving a positive answer from the researchers (graded with 3), while 

one pair ignored the step (receiving a grade of 1) and subsequently repeated the exper-

iment. The remaining 24 pairs of students (92%) saved the data as specified in the 

worksheet and received a grade of 4. 

3.5 Step 6: Analysis of the acceleration graph 

Students were asked to study the graph of acceleration as a function of time (Figure 

3) and to determine not only the area of the graph indicating where the body slid 

down the inclined plane, but also the area where the body was immobilized (by the 

student at the base of the plane).  

Findings: As previously mentioned, in “The Worksheet and the Pilot Implementa-

tion” section, the students had significant difficulty in interpreting the graph, a situa-

tion which was also evident during the actual implementation. However, since the 

purpose of this study is to investigate the ability of students to use their MPs to com-

plete all the steps in the process of an experiment by following the instructions in a 

worksheet, a goal that does not require students to understand the concepts involved, 

the researchers intervened in this step and explained the form of the diagram to the 

students. As already mentioned in the section “The Implementation and the Evalua-

tion”, this step was not graded (and therefore is not included in Table 1), but neverthe-

less gives rise to the reflection that will be developed in the section “Discussion and 

Conclusions”. 

 

Fig. 3. Calculation of the average value of the acceleration  

with the “Sparkvue” application 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

3.6 Step 7: Finding the mean acceleration value 

Students had to choose an appropriate scale and focus (zoom) on the graph on their 

MP screens properly so that the area showing the movement of the body on the in-

clined plane was clearly visible at the point where a constant acceleration (plateau 

area) was expected to occur. They then had to draw (by sliding their fingers on the 

screen) an appropriate rectangular area (ROI-range of interest) which would include 

the whole of the plateau or a sufficient part of it (Figure 3). Finally, using the appro-

priate tools of the application, the average value of acceleration in the chosen area 

would be calculated automatically, and this value had to be recorded. 

Findings: As mentioned above in the “the Implementation and the Evaluation” 

section, the researchers conducted a meta-analysis of all the graphs submitted by the 

26 student pairs after the experiment, at which time they assigned a final evaluation 

score to step 7, taking into consideration the students’ conclusions and choices. Nine 

pairs (35%) completed the step well and received a grade of 4, ten pairs (38%) whose 

graphs had poor focus (zoom) or minor problems in the selection of the ROI were 

graded a 3, four pairs (15%) who had major problems in the selection of the plateau 

were graded a 2, and three pairs (12%), which had either not zeroed out the accelera-

tion at the plane, or chosen the point of impact of the body with the base of the in-

clined plane instead of the area where the acceleration was constant, received a grade 

of 1. 

3.7 Step 8: Saving changes 

In this step the students were asked to save the changes they had made during the 

intervening steps 6 and 7 to the original file they had created during step 5 (so that 
their choice of the ROI and measured acceleration would also be stored), and then to 

send this file via email to the researchers. As mentioned previously, the purpose of 

this step was to provide the researchers with a complete picture of all the data ob-

tained by students during the process of performing the experiment in order to analyze 

them after the experiment had been completed.  

Findings: All 26 pairs received a grade of 4 as both the changes were saved cor-

rectly, and the data was sent to the researchers without problems. 

3.8 Step 9: Calculations 

In this last step of the process, the students were asked to use the mean value of the 

acceleration (from Step 7) as well as the measurement of the angle φ (Step 3) to calcu-

late the coefficient of kinetic friction between the body and the inclined plane, using 

equation (1). 

Findings: The students used the calculator of their MP in scientific mode. Alt-

hough the conversion between rad and degrees of the angle measurement had been 

explained during the pre-implementation briefing, one team could not perform the 

specific conversions and was led to miscalculations before being assisted by the re-

searchers (receiving a grade of 2). Also, six pairs (23%) kept all the decimal places 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

both in the calculation of the acceleration and in the calculation of the kinetic friction 

coefficient (resulting in a grade of 3). The remaining 73% of the pairs completed the 

operations and calculations without problems (receiving a grade of 4). 

4 Discussion-Conclusion 

The aim of the present work is to investigate the difficulties students face when 

they conduct an experiment with the help of a “smart” mobile device that they bring 

with them into the laboratory. It is important to note that the students were thoroughly 

briefed by the researchers before the implementation of the experiment since we con-

sidered it necessary to provide detailed instructions and explanations relating to the 

procedures, at least during the first application of the process in a classroom or in a 

lab, as students were likely to be unfamiliar with the specific applications.  

The data analyzed were the researchers’ assessments of students’ performance of 

each step, the final evaluation sheets completed by the researchers who had monitored 

the pairs of students and, finally the files that the students had emailed to the re-

searchers after the completion of the experiment. Based on these data, each pair was 

evaluated on the various steps involved in the performance of the experiment, steps 

which incorporate the ten key points mentioned in the “Implementation and Evalua-

tion” section above.  

The analysis shows that the difficulties encountered by the students were mainly in 

the steps requiring detailed manipulations on the screen of their MPs. Specifically, 

these steps concerned the selection of an appropriate measurement rate and number of 

decimal places in the acceleration measurements, as well as the correct selection of 

the plateau area from the graph and the calculation of the acceleration. However, even 

in these steps, most groups performed well or with little intervention from the re-

searchers. The steps which students found easier to manage were those of storing data 

and saving changes, probably because they were familiar with these types of tasks 

from experience with other applications. 

In general, the students did not face any particular difficulties in performing the 

experiment and, from our first assessment, were probably not presented with greater 

difficulties than those they would have faced in a classic experiment with school in-

struments and devices that they had not used before. Of course, this latter conclusion 

needs further corroboration. However, given that the students performed the experi-

ment using an MP for the first time, we consider it reasonable to speculate that if they 

had used MP sensors more systematically to take measurements in the school lab the 

results would have been even better. 

As already mentioned, students encountered considerable difficulty in the interpre-

tation of the acceleration time diagram, which required the decisive intervention of 

the researchers; this particular difficulty was not investigated in depth, as it was not 

the aim of the present work. However, on first assessment it seems to be related to the 

students’ difficulty in relating the concepts of physics as taught in class to their empir-

ical content. Also, in the case of MPs, the high frequency and accuracy of measure-

ments resulted in details that are not in line with the theoretical model that students 

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Paper—How Effectively Can Students’ Personal Smartphones be Used as Tools in Physics Labs? 

have learned in class or from textbooks. For example, when the body slides down on 

the inclined plane there are vibrations, and the kinetic friction coefficient may not be 

constant; thus, the time acceleration diagram is not a constant function, as predicted 

by the theoretical model. Therefore, a potential extension of the present research 

would be to investigate the students’ difficulties in interpreting the data, resulting 

from measurements made with applications that utilize the sensors of “smart” mobile 

devices.  

As the period of quarantine due to the covid-19 pandemic has brought to light, in 

an environment of distance learning there is also a need for students to engage in 

experimental work during a science course. The present study showed that a large 

percentage of students are able to perform experiments in which they take and process 

measurements using a MP by following the instructions on a worksheet. This gives us 

a reason to think that with proper preparation, students could perform experiments 

with simple materials at home, using their MPs to take and process the necessary 

measurements. Students could then send the results, along with a video of them con-

ducting the experiment, to the teacher for evaluation. This is a research proposal that 

we are already implementing. 

The present paper is a case study involving a particular class of a secondary school; 

therefore, it has certain limitations and the results cannot be generalized without pre-

cautions and further studies. For example, one obvious limitation is that although the 

research was focused on the ability of students to use the devices in the context of a 

physics lab, it was not carried out in real laboratory conditions so it was not possible 

to check whether the teacher could respond to the coordination of a large number of 

groups. However, the sample of 52 students is large enough to permit us to draw the 

first conclusions. Thus, it may be worthwhile to repeat the research in a typical school 

laboratory with all students of a class present in order to determine whether any prob-

lems may arise, such as students becoming distracted or the teacher’s coordination of 

a large number of students [9] [27] [29]. Finally, as already mentioned, challenges for 

future research concern students’ ability to perform experiments using MPs and sim-

ple materials, as well as student’s ability to interpret the graphs depicted on MPs 

when using appropriate apps to take measurements.  

In conclusion, we can support that the results of our study show that the integration 

of students’ “smart” mobile devices in the performance of physics experiments in the 

classroom or in the school lab is possible and does not present any particular prob-

lems. This conclusion is reinforced by the findings of previous research [28], whose 

results show that the wide variety of students’ MPs does not cause problems and does 

not lead to statistically significant discrepancies in the results of the experiments. 

However, this integration presupposes the proper planning by the teacher, and the 

dedication of appropriate time both for the preparation of the students for the activity 

and for the installation of the necessary applications in the devices. 

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6 Authors 

Serafeim Tsoukos has a PhD in Medical Physics. He is currently teaching physics 

in the 2nd Experimental Junior High School of Athens, Greece. He is interested in the 

use of smartphones and technology in physics education.  

Panagiotis Lazos is a PhD student in the Faculty of Primary Education of the Na-

tional and Kapodistrian University of Athens. He is currently the head of the 4th La-

boratory Center of Natural Sciences of Athens. His scientific and research interests 

include the study of the use of smart mobile devices and microcontrollers in physics 

education, especially in the school science laboratory.  

Pavlos Tzamalis has a PhD in Crystallography. He is currently in the teaching 

staff of the physics laboratory in the Biotechnology Department of the Agricultural 

University of Athens. He is interested in the use of technology to enhance learning in 

physics. 

Alexandros Kateris has a PhD in Medical Physics. He is currently teaching phys-

ics in the 2nd Experimental Lyceum of Athens, Greece. He is interested in m-learning 

especially in physics education. 

Athanasios Velentzas has a PhD in Science Education. He is currently in the 

teaching staff of the physics department in the School of Applied Mathematical and 

Physical Sciences of the National Technical University of Athens. His research areas 

include m-learning, and real/virtual/ thought experiments in physics education.  

Article submitted 2021-03-01. Resubmitted 2021-05-05. Final acceptance 2021-05-06. Final version 
published as submitted by the authors. 

iJIM ‒ Vol. 15, No. 14, 2021 71

https://doi.org/10.1080/02635143.2018.1526170
http://dx.doi.org/10.3991/ijim.v8i3.3873