A Design of Biomeditronics Analysis Bed Parameter using Atmega 16 Microcontroller
|International Journal of Electronics and Communication Engineering|
|© 2016 by SSRG - IJECE Journal|
|Volume 3 Issue 8|
|Year of Publication : 2016|
|Authors : Sachin Chauhan, Shivam Sawarn, Shubham Sawarn, Sagar Raj and Udaybhan Chaudhary|
How to Cite?
Sachin Chauhan, Shivam Sawarn, Shubham Sawarn, Sagar Raj and Udaybhan Chaudhary, "A Design of Biomeditronics Analysis Bed Parameter using Atmega 16 Microcontroller," SSRG International Journal of Electronics and Communication Engineering, vol. 3, no. 8, pp. 1-5, 2016. Crossref, https://doi.org/10.14445/23488549/IJECE-V3I8P101
Biomedical field does not have anyboundation as the technology is developing and the patients are increasing day by day. After working in the practical exposure with the surroundings, we found that sensors are very valuable.It is reasonable at both the ends. It has proved its need till now and is showing its abilities incessantly. This technology has the ability to shape the future of biomedical. The main aim of paper is to understand the technology better on the practical basis. It perfectly helps an engineer to get an overlook of society. We get technical exposure to every old and new instrument and technical advances. A step-by-step approach in designing the Atmega-16 microcontroller based system for measurement and control of the essential parameters. The results obtained from the measurement have shown that the system performance is quite illusive and accurate. The system has successfully overcome quite a few disadvantages of the existing systems by minimizing the power consumption, maintenance and complexity, at the same time providing a complete form of fulfillment to the health trades. The continuously decreasing costs of hardware and software, create a wider acceptance of electronic systems in different fields, and an emerging control system industry in several areas of inclusive production, will result in reliable control systems that will address several aspects of variable qualities of production. Further corrections will be made as quite reliable and primitively expensive and more useful as sensors are developed for use in medical science .Although the enhancements mentioned in the paper may seem far in the future, the required technology and components are present, many such sensors have been independently developed, or are at least tested at a prototype level. Also, differentiation of all these technologies is not a big task and can also be successfully carried out.
Biomedical, sensors, load sensor, temperature sensor, heart-beat sensor.
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