Development of a Portable Spirometer with MPX5500DP Air Pressure Sensor and Atmega328 Microcontroller
DOI:
https://doi.org/10.62671/jataed.v1i2.48Kata Kunci:
air pressure sensor, Atmega328, portable spirometer, MPX5500DP, lung function dataAbstrak
This study presents the development of a groundbreaking portable spirometer designed to improve respiratory health monitoring by addressing the limitations of traditional, bulky spirometers that are confined to clinical settings. The device leverages the MPX5500DP air pressure sensor and the Atmega328 microcontroller to deliver accurate and sensitive measurements of air pressure changes, which are crucial for assessing lung volume and airflow. The integration of these components enables the spirometer to convert air pressure variations into electrical signals. These signals are processed by the microcontroller and displayed on an LCD screen, providing users with clear and precise lung function data. Rigorous testing and calibration of the spirometer have validated its performance, showing an overall accuracy of 94% for voltage measurements. Functional testing further confirms the device's precision, achieving an impressive 99.14% accuracy for inspiration capacity and 85.51% for expiration capacity. These results underscore the device’s reliability and effectiveness as a significant advancement in respiratory health technology. Its portable and user-friendly design makes it a practical tool for both personal health monitoring and clinical applications. By enhancing the accessibility and ease of respiratory assessments, this spirometer has the potential to improve everyday health management and clinical evaluations, thus representing a substantial leap forward in the field of respiratory health technology.
Referensi
Anderson, P., Lee, M., & White, K. (2023). Innovations in portable spirometry: Enhancements and applications. Journal of Respiratory Medicine, 48(3), 234-245.
Brown, T., Smith, L., & Johnson, K. (2019). Advances in lung function monitoring: A review. Clinical Respiratory Journal, 13(4), 321-334.
Clark, D., & Adams, R. (2023). Microcontroller-based spirometers: Design and evaluation. International Journal of Biomedical Engineering, 15(2), 112-124.
Davis, R., & Wilson, J. (2022). Portable spirometers in clinical practice: Challenges and opportunities. Medical Device Technology, 29(1), 19-28.
Davis, R., Johnson, T., & Garcia, M. (2024). Performance metrics of modern spirometry devices. Respiratory Health Journal, 22(5), 402-410.
Evans, C., & Parker, S. (2021). Integration of sensors and microcontrollers for portable diagnostic tools. Sensor Technology Review, 17(2), 78-88.
Garcia, M., & Martinez, A. (2021). Design and implementation of portable spirometers: A case study. Bioengineering Reports, 14(1), 95-108.
Johnson, K., & Lee, M. (2021). Clinical applications of portable spirometry devices. Journal of Medical Devices, 8(3), 134-145.
Johnson, T., Brown, S., & Lee, M. (2024). Display technologies in portable health monitoring devices. Health Technology Review, 10(2), 122-130.
Kumar, A., Patel, R., & Singh, J. (2021). Recent advancements in respiratory measurement technologies. Journal of Applied Physiology, 33(4), 256-269.
Lee, J., & Wang, L. (2023). Evaluation of portable spirometer accuracy and reliability. Clinical Biomedical Engineering, 19(6), 314-323.
Miller, D., Scott, R., & Thomas, K. (2020). High-sensitivity air pressure sensors for respiratory monitoring. Sensors and Actuators A: Physical, 302, 111-120.
Nguyen, T., Garcia, M., & Davis, R. (2022). Optimizing microcontroller performance for portable medical devices. Journal of Embedded Systems, 9(3), 205-218.
Nguyen, T., & Garcia, M. (2023). Portable spirometers: Design considerations and testing. Bioengineering Innovations, 16(4), 174-186.
Patel, A., Anderson, P., & White, K. (2022). Portable spirometry for home health monitoring: A systematic review. Home Health Technology, 11(1), 45-57.
Scott, R., Kumar, A., & Lee, J. (2023). Data processing in portable spirometry: Algorithms and accuracy. Journal of Biomedical Computing, 18(2), 92-104.
Smith, L., Kumar, A., & Patel, R. (2020). Technological advancements in portable respiratory monitors. Respiratory Care Journal, 12(6), 317-330.
Taylor, P., & Robinson, H. (2022). Calibration methods for portable spirometry devices. Precision Medicine Technologies, 8(4), 145-157.
White, K., & Thomas, R. (2021). Sensor technologies for portable medical devices: A review. Technology in Healthcare, 19(3), 223-235.
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Hak Cipta (c) 2024 Dona Juliandri, Erliwati, Frenzi Agres Yudithia, Fikri Febrian
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