Indonesian Review of Physics, Volume 1, Number 1, 2018 

 
15 

Architecture of Atwood Machine Props with Sensor-based Passive 

Infrared 

 

Delia Achadina Putri1 and Dandan Luhur Saraswati2 
1,2Pendidikan Fisika Universitas Indraprasta PGRI, Indonesia 
Jl. Raya Tengah No.80 Kel. Gedong, Kec. Pasar Rebo, Jakarta Timur 
Email: deliachadina@gmail.com 

 

The aim of this research is to develop Atwood machine propswith sensor-based PIR (Passive 
Infrared) to determine the acceleration value of earth gravity. This type of research is an 
experiment conducted in the physics laboratory of Universitas Indraprasta PGRI. Atwood 
machine was developed by using PIR (Passive Infrared) sensors to detect the movement of the 
objects used. Based on the trialof the result of the data analysis experiment tool, the 
acceleration of gravity was obtained (9.87 ± 0.08) m/s2. Whereas the value of acceleration of 
gravity in the literature is 9,80665 m/s2. The obtained results shows that the acceleration of 
gravity obtained in this research is not much different from the acceleration value of gravity 
found in the literature so that Atwood machine tool that is developed by using PIR sensor is 
recommended to be one alternative tool in determining the acceleration of earth gravity. 
 

 
Key words: Acceleration of Gravity, Atwood machine, PIR (Passive Infrared) sensors 
 

I. Introduction 

Physics is not merely a theory lesson where its benefits 
cannot be perceived by society. Physics is one of the 
natural sciences which became the basis of a wide range 
of technologies in the world [1]. Physics study about 
natural phenomena or subject in the scope of space and 
time, so that the implementation of physics can be used 
to study how this natural phenomenon occurs [2]. In 
physics various motion of objects started from the 
motion of marbles, motion of planet rotation, motion of 
rocket, or even the motion of an apple falling from the 
tree are studied in the branch of physics called 
mechanics. In general mechanics is divided in two 
subjects, called the dynamics and kinematics. Dynamics 
study about motion of objects and its causes and 
kinematics study about motion of objects only without 
necessarily know the causes [3]. 

The Atwood machine is a tool that can be used to 
analyze the mechanisms used to measure acceleration. 
Typically, a teacher demonstrating the study of gravity 
only to prove the existence of gravity acceleration, for 
example by removing an object from a certain height, 
but students have never directly done the experiment to 
find out how to determine the acceleration value of 
gravity that they have been reading through books. The 
object will fall with an acceleration caused by the 
gravitational forces of the Earth or Earth’s gravity. This 
Earth’s gravity causes an object falling from a certain 

height with an acceleration known as the acceleration of 
Earth’s gravity. 

The acceleration of Earth’s gravity is influenced by 
the distance of an object from the Earth’s center and the 
density of Earth’s composition in that coordinate 
[4].The acceleration of Earth’s gravity symbolized by ' g 
' indicates the average acceleration produced by 
gravitational field on the Earth surface with unit m/s2 
[5].With the advance of science, technology and also 
latest innovation, it provide an opportunity for 
researchers to create Atwood machine props. Nowadays, 
Atwood’s machine is used with purposes to demonstrate 
uniformly accelerated motion with smaller acceleration 
than the gravitational acceleration g[6]. 

The Atwood’s machine is a device where two masses 
hang from the ends of string passing over a pulley that 
can freely rotate on its horizontal axis [7]. The Atwood 
machine is an experimental tool used to observe 
uninform mechanics’ law of motion. This tool began to 
be developed around the eighteenth century to measure 
the acceleration of gravity. The props used to describe 
the relationship between stress, potential energy and 
kinetic energy using two ballast (different mass) which 
are m1 (M+m)  and m2 (M) connected by a string on a 
pulley. Objects with larger mass (m1) is higher in 
position than the lighter mass (m2). Thus, an object 
with mass m2 will move down because of the effect of 
gravitational acceleration and pull m1 because of the 
connected rope in the pulley. 

mailto:deliachadina@gmail.com


Volume 1, Number 1, 2018 
Putri & Saraswati                Architecture of Atwood Machine Props with Sensor-based Passive Infrared 

 

16 
 

Simply put, this tool is composed of a rope connected 
to a pulley, which at the end of the rope is hooked with 
mass of loadsm1 and m2. If the mass of the object m1 
and m2are equal   (m1 = m2), then both will be silent. 
However, if the mass of the object m2 is greater than the 
mass of the object m1, then the mass m1 will be pulled 
by the mass. 

In this research, the PIR sensor used is HC-SR501 
type. Needs of HC-SR501 sensor input according to its 
datasheet is 4.5-20V DC with maximum current 50uA. 
The ability to detect the sensor from 3-7 meters with 
delay between 5-200 seconds. The angle range is 140 ° 
[8]. 

II. Literature Review 

Today, it is common that many experimental physics 
programs include Atwood machines and variable masses 
to introduce more complex concepts in physics. To 
study the mass dynamics that make up the Atwood 
variable machine, the lab usually uses intelligent pulleys 
[9]. 

In thisAtwood machine contain elements of 
translational Motion that is uninform linear 
motion(GLB) and accelerated linear motion (GLBB). 
According to Marthen Kanginan, uninform linear 
motionis a rectilinear  motion of an object, where in this 
motion its velocity fixed or no acceleration, so the 
distance traveled is speed times time [10]. While the 
accelerated linear motion is rectilinear motion of an 
object, where the velocity is changing [11]. Not only the 
uninform linear motion or accelerated linear motion but 
the working principles of the pulley is also appl. A 
pulley is a wheel with a rope around and used to ease the 
work of people [12]. 

The acceleration of earth's gravity is the acceleration 
experienced by objects that fall freely from a certain 
height toward the Earth's surface. Based on the 
literature, the earth's gravity acceleration value is equal 
to 9,80665 m/s2[13]. The direction of gravitational 
acceleration is toward the center of the Earth or 
perpendicular to the surface of the ground. The 
magnitude of gravitational acceleration in several 
different places may not be exactly equal to 9.80665 
m/s2. This is due to the difference in mass density and 
distance of a place from the center of the Earth[14]. 

The sensor is the equipment used to change a physical 
quantity to electricity quantity so it can be analyzed with 
specific electrical network[15].Passive Infrared sensor is 
a low cost, low power and reliable sensor [16]. PIR-
based system saves power consumption and memory 
space [17].  IR filter contained in the PIR sensor is 
capable of filtering the wavelength of passive infrared 
light between 8 to 14 micrometers. This infrared ray is 
then captured by the pyro-electric sensor which is the 
core of the PIR sensor. The pyro-electric sensor consists 

of gallium nitride, cesium nitrate and litium tantalite 
which produces an electric current [8].However, unlike 
most of others infrared where they consist of LED and 
fototransistor, PIR does not emit anything as IR LEDs. 
In accordance with the name ‘passive’, this sensor only 
responds energy from the passive infrared beams which 
are owned by any objects detected by it[18]. PIR sensor 
has two sensing elements connected to the inputwith the 
order as shown in the following figure [19]. 

 
Figure 1. PIR Sensor Wave Range Direction 

III. Research Methods/Experiment 

1. Tools and materials: 
Atwood machine consist of: 
a. The pole with a pullet at the top 
b. A hanging rope with a negligible mass 
c. Two load of m1 (just above the sensor hole of 

timer 1) and m2 (located on the stopper) 
cylindrical with a sharp point underside 

d. Stopper to hold m2 
e. Sensor 1 (at point A) used to turn on 

stopwatch 1. Sensor 2 (at point B) with double 
function that are turn off stopwatch 1 and 
simultaneously turn on stopwatch 2. Sensor 3 
(at point C) turnoff stopwatch 2. 

f. The Stopwatch box, which contains stopwatch 
1 to record time from point A to point B. 
Stopwatch 2 to record time from point B to 
point C. 
 
 
 
 
 
 
 
 

 



Volume 1, Number 1, 2018 
Putri & Saraswati                Architecture of Atwood Machine Props with Sensor-based Passive Infrared 

 

17 
 

 
2. Tool Design: 

 

 
Figure 2. Atwood Tool Design 

 

3. Step Tes Tool : 

a. Prepare the atwood machine device in a flat 
ground. 

b. Set m1 right above the timer sensor 1 and 
located in thecenterhole of the sensor and one 
load again on stopper (m2). 

c. Turn on all stopwatch and reset to zero (0) 
d. The size of the components required for the 

calculation of the Atwood machine is as 
follows: 

 
Table I. Table of Component Amount 

Quantity Units (kg)z 
Mass of the load 0,07 

Mass of the pulley 0,4 
 

e. Press the stopper so mass m2 and m1 apart from 
the andmoving down pass the hole sensor timer 
1 to turn on the stopwatch 1, then pass hole 
sensor timer 2 with double function that is 
turning off stopwatch 1 and simultaneously 
turn on the stopwatch 2, and the last pass 
through the sensor hole 3 to turn off the 
stopwatch 2. 

f. Observe and record how much time is shown 
on stopwatch 1 (time from point A to B (tAB)) 
and stopwatch 2 (time from point B to C 
(tBC)). 

g. Calculate the acceleration value of gravity by 
using the formula: 

𝑔 =
(2�̅�+�̅�+𝑚𝑝̅̅̅̅̅).�̅�

�̅�
  (1) 

 

IV. Research Results and Discussion 

In this research we get experiment data that is: 
Table II. Experiment Data 

No Load 
Mass [M] 

(kg) 

Mass 
of 

Ballast 
[m] 
(kg) 

Time A-B 
[tAB] (s) 

Time 
B-C 
[tBC] 
(s) 

Acceleration
[a] (m/s2) 

1 0,070 0,010 2,75 1,34 0165530 
2 0,072 0,011 2,70 1,24 0,180998 
3 0,070 0,011 2,50 1,30 0,182820 
4 0,069 0,012 2,45 1,35 0,176045 
5 0,071 0,010 2,68 1,26 0,179207 

 
After the data were analyzed and the acceleration 

value of earth gravity was calculated by using the 
equation (1), so the earth gravity acceleration value in 
this study was (9,87 ± 0,08) m/s2. These results are 
better than research conducted by Syahrul, et al, who get 
the acceleration value of earth gravity that is 9,619 
m/s2[20]. The value obtained in this study is not much 
different from the literature that underlie this research 
which is 9,80665 m/s2. 

V. CONCLUSION 

1. A simple atwood machine can be used to measure 
the magnitude of earth’s gravitional acceleration 

2. The acceleration value of gravity obtained in this 
research is equal to (9,87 ± 0,08) m/s2. The value 
obtained in this study is not much different from the 
literature that underlie this research which is 
9,80665 m/s2. 

 

Acknowledgement 
Researchers say thanks to Oki Mustava and Dr. 

Dwi Sulisworo, M.T who has been a reviewers of the 
journal that has researchers create and thanks to the 
Indonesian Review of Physics that can publish our 
journal as well as the physics laboratory of the 
UniversitasIndraprasta PGRI which has become our 
research place. 

 

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Volume 1, Number 1, 2018 
Putri & Saraswati                Architecture of Atwood Machine Props with Sensor-based Passive Infrared 

 

18 
 

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https://repository.unikom.ac.id/30330/1/2.syahrul-
pengukur-percepatan-gravitasi.pdf diakses pada tanggal 28 
Mei 2018 

 

https://repository.unikom.ac.id/30330/1/2.syahrul-pengukur-percepatan-gravitasi.pdf
https://repository.unikom.ac.id/30330/1/2.syahrul-pengukur-percepatan-gravitasi.pdf

	Delia Achadina Putri1 and Dandan Luhur Saraswati2
	Key words: Acceleration of Gravity, Atwood machine, PIR (Passive Infrared) sensors
	Acknowledgement
	Researchers say thanks to Oki Mustava and Dr. Dwi Sulisworo, M.T who has been a reviewers of the journal that has researchers create and thanks to the Indonesian Review of Physics that can publish our journal as well as the physics laboratory of the U...
	Literature