Portable And User-Friendly Air Watch System based on IoT

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Year : 2024 | Volume :15 | Issue : 03 | Page : –
By
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Umesh Pinjarkar,

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Indrayani Bhujade,

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Sejal Birgawale,

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Suyesh Shinde,

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Kulashri Kasbeoraph,

  1. Assistant Professor, Saraswati College of Engineering, Pune, Maharashtra, India
  2. Student, Saraswati College of Engineering, Pune, Maharashtra, India
  3. Student, Saraswati College of Engineering, Pune, Maharashtra, India
  4. Student, Saraswati College of Engineering, Pune, Maharashtra, India
  5. Student, Saraswati College of Engineering, Pune, Maharashtra, India

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The Internet of Things (IoT) based Air Monitoring System is a novel approach to monitoring air quality in real-time. With the increasing concerns over pollution and its impact on human health, our IoT based air monitoring system offers a solution to gather and analyze air quality data efficiently. The system utilizes IoT devices like Node MCU and sensors like MQ135 and DTH11 to collect data such as temperature, air quality and humidity respectively, providing valuable insights for individuals and authorities to make informed decisions for a cleaner and healthier environment. Sophisticated Real-time air Monitoring systems have been developed because of growing global awareness of air quality and its direct impact on human health. The Internet of Things (IoT) based portable and user-friendly air watch system seeks to give people and communities useful information about air pollution levels. This analysis delves into the technical underpinnigs of Internet of Things (IoT) based air monitoring systems, emphasizing their portability, user friendliness, and capacity to integrate many sensors to gather data on a range of contaminants. It goes into additional detail about the practical applications of these systems, their importance in reducing health hazards, and the techniques used in their development and implementation. A discussion of upcoming trends and potential enhancements, for broader adoption and scalability rounds up the review.  

Keywords: MQ135 Gas Sensor, DTH11 Temperature Sensor, Node MCU, Internet of Things, Microcontroller, RAM, Wi-Fi Module

[This article belongs to Journal of Control & Instrumentation (joci)]

How to cite this article:
Umesh Pinjarkar, Indrayani Bhujade, Sejal Birgawale, Suyesh Shinde, Kulashri Kasbeoraph. Portable And User-Friendly Air Watch System based on IoT. Journal of Control & Instrumentation. 2024; 15(03):-.
How to cite this URL:
Umesh Pinjarkar, Indrayani Bhujade, Sejal Birgawale, Suyesh Shinde, Kulashri Kasbeoraph. Portable And User-Friendly Air Watch System based on IoT. Journal of Control & Instrumentation. 2024; 15(03):-. Available from: https://journals.stmjournals.com/joci/article=2024/view=0

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References
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  1. Dharmesh Rajesh Solanki, Shruti Sambhaji Bhosale, Madhura Dilip Gite, Pradnya Uttamrao Gaikwad, Umesh Pinjarkar. NodeMCU in IoT-Based Weather forecasting and surveillance: A Review of Applications and Future. Research & Reviews: Journal of Space Science & Technology. 2023; 12(2): 13-20. https://sciencejournals.stmjournals.in/index.php/RRJoSST/issue/view/559.
  2. Shravana Shetty, Mahaveera K, Suraksha S Bolar, Suman Kumar, Sushmitha G J. Air Quality Monitoring System Using Node Mcu”, International Journal Of Creative Research Thoughts(IJCRT), April 2023; 11(6): 96-105.
  3. T.P. Lumbangaol, Ruben Cornelius Siagian, Fine Eirene Siahaan, Erni Kusrini Sitinjak. IOT-Based Pollution and Air Quality Monitoring Equipment with ESP-8266. Proceedings of the 6th Batusangkar International Conference, BIC 2021, 11 – 12 October, 2021, Batusangkar-West Sumatra, Indonesia. http://dx.doi.org/10.4108/eai.11-10-2021.2319568
  4. Anand Jayakumar A., Praviss Yesyand T. K., Venkatesh Prashanth K. K., Ramkumar K. IoT Based Air Pollution Monitoring System. International Research Journal of Engineering and Technology (IRJET).2021; 8(3):
  5. Atul Kulkarni, Debajyoti Mukhopadhyay. Internet of Things Based Weather Forecast Monitoring System. Indonesian Journal of Electrical Engineering and Computer Science. 2018; 9(3): 555-557
  6. Gillis, Alexander, Kinza Yasar (2021). “What is internet of things (IoT)?”. IOT Agenda. [Online]. Available from https://www.techtarget.com/iotagenda/definition/Internet-of-Things-IoT Retrieved 17 August 2021.
  7. Brown, Eric (20 September 2016). “21 Open-Source Projects for IoT”. Linux.com. Retrieved 23 October 2016. [Online]. Available from https://www.linux.com/news/21-open-source-projects-iot/
  8. Parmar, S. Lakhani and M. K. Chattopadhyay, “An IoT based low cost air pollution monitoring system,” 2017 International Conference on Recent Innovations in Signal processing and Embedded Systems (RISE), Bhopal, India, 2017, pp. 524-528, doi: 10.1109/RISE.2017.8378212.
  9. Kennedy Okokpujie, Etinosa Noma-Osaghae, Odusami Modupe, Samuel John and Oluga Oluwatosin. A Smart Air Pollution Monitoring System. International Journal of Civil Engineering and Technology. September 2018; 9(9): 799-809.
  10. Gaurav Rout, Sairam Karuturi and Padmini T. N. Pollution Monitoring System Using IoT. ARPN Journal of Engineering and Applied Sciences. March 2018; 13(6): 2116-2123.
  11. A. Postolache, J. M. Dias Pereira and P. M. B. Silva Girao, “Smart Sensors Network for Air Quality Monitoring Applications,” in IEEE Transactions on Instrumentation and Measurement, vol. 58, no. 9, pp. 3253-3262, Sept. 2009, doi: 10.1109/TIM.2009.2022372.
Regular Issue Subscription Review Article
Volume 15
Issue 03
Received 23/08/2024
Accepted 16/09/2024
Published 24/10/2024
74

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