An Automation System for Controlling Streetlights and Monitoring Objects Using Arduino
<p>The architecture design of the automatic street light control system.</p> "> Figure 2
<p>Circuit design of automation system based on night and objects’ detection.</p> "> Figure 3
<p>The flow diagram of the automation system based on night-time object detection.</p> "> Figure 4
<p>Result diagrams of the automatic streetlight control system that switches to DIM at night and HIGH at object detection. (<b>a</b>) In the day-time simulation, the LEDs are not glowing. (<b>b</b>) In the night-time representation, the DIM LEDs are glowing. (<b>c</b>) An object in front of first IR obstacle avoidance sensor; the first set of HIGH LEDs are glowing while the remainder are in DIM mode. (<b>d</b>) Motion in front of the second IR obstacle avoidance sensor; only the second set of LEDs are glowing HIGH, and all the others are in a DIM state.</p> "> Figure 5
<p>Circuit design of the automation system based on object detection and an automatic door system.</p> "> Figure 6
<p>The flow diagram of the automation system based on object detection.</p> "> Figure 7
<p>Result diagrams of enhanced work with an automatic door system and only an ON/OFF capability. (<b>a</b>) During a day/night-time simulation, the LEDs are not glowing. (<b>b</b>) Object in front of the first IR obstacle avoidance sensor; the HIGH LEDs are glowing. (<b>c</b>) Motion in front of the third IR obstacle avoidance sensor; the third set of LEDs are glowing. (<b>d</b>) An object detected is in front of the door, so it is automatically opened, and the relevant LEDs are glowing.</p> "> Figure 8
<p>Serial monitor output according to traffic flow.</p> ">
Abstract
:1. Introduction
2. Materials and Methods
2.1. Electronic Components
2.1.1. IR Obstacle Avoidance Sensor
2.1.2. LDR
2.1.3. Arduino Uno
2.1.4. L298 Motor Module
2.2. Automation System Based on Night-Time Object Detection
Results and Discussion
2.3. An Automation System Based on Object Detection
Results and Discussion
3. Conclusions
Supplementary Materials
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Components | Specifications |
---|---|
IR obstacle avoidance sensor [11] | Voltage: DC 3–5 V; Range 2–30 cm; Angle: 35° |
LDR [10] | Voltage: DC 3–5 V; Diameter: 5 mm |
Arduino Uno [12,13] | 22 pins; Operating voltage: 6–20 V |
LEDs [51] | Diameter: 5 mm; Operating voltage: 5 V |
Resistors [52] | 100 ohm; 220 ohms |
L298 Motor Module [53] | Operating voltage: 5 V; Max power: 25 W |
Functionality | Old Systems | Proposed System |
---|---|---|
Based on Arduino | Yes | Yes |
Operates with LDR and IR | Yes | Yes |
DIM/FULL light capability with object detection | No | Yes |
Displays the total number of objects passing through a road | No | Yes |
Automatic door system | No | Yes |
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Share and Cite
Mumtaz, Z.; Ullah, S.; Ilyas, Z.; Aslam, N.; Iqbal, S.; Liu, S.; Meo, J.A.; Madni, H.A. An Automation System for Controlling Streetlights and Monitoring Objects Using Arduino. Sensors 2018, 18, 3178. https://doi.org/10.3390/s18103178
Mumtaz Z, Ullah S, Ilyas Z, Aslam N, Iqbal S, Liu S, Meo JA, Madni HA. An Automation System for Controlling Streetlights and Monitoring Objects Using Arduino. Sensors. 2018; 18(10):3178. https://doi.org/10.3390/s18103178
Chicago/Turabian StyleMumtaz, Zain, Saleem Ullah, Zeeshan Ilyas, Naila Aslam, Shahid Iqbal, Shuo Liu, Jehangir Arshad Meo, and Hamza Ahmad Madni. 2018. "An Automation System for Controlling Streetlights and Monitoring Objects Using Arduino" Sensors 18, no. 10: 3178. https://doi.org/10.3390/s18103178
APA StyleMumtaz, Z., Ullah, S., Ilyas, Z., Aslam, N., Iqbal, S., Liu, S., Meo, J. A., & Madni, H. A. (2018). An Automation System for Controlling Streetlights and Monitoring Objects Using Arduino. Sensors, 18(10), 3178. https://doi.org/10.3390/s18103178