Smart Vibration Control Systems: The Role of Digital Output in Advancing Two-Degree-of-Freedom Design
DOI:
https://doi.org/10.70112/arme-2024.13.2.4279Keywords:
Two-Degree-Of-Freedom (2-DOF), Vibration Measurement System, Digital Output, Structural Health Monitoring, Digital Signal ProcessingAbstract
This paper focuses on the development of a two-degree-of-freedom (2-DOF) vibration measurement system with digital output, designed for applications in mechanical engineering, structural health monitoring, and industrial processes. The primary objective is to design and implement a system that accurately measures and analyzes vibrations in two degrees of freedom, providing real-time digital insights for further analysis and decision-making. The system consists of a mechanical setup incorporating springs and dampers to simulate 2-DOF vibrations. Sensors are employed to detect vibrational responses, and the acquired data is processed using a microcontroller. The processed information is then displayed digitally, enabling precise monitoring and analysis. The research is conducted in four main phases: designing the mechanical system, integrating the sensors and microcontroller, developing the digital output interface, and testing the final prototype. By leveraging digital signal processing and real-time data acquisition, the proposed system enhances the accuracy and reliability of vibration analysis. The expected outcome is an efficient and user-friendly vibration measurement system capable of improving the understanding and control of vibrational behavior in various environments. This study contributes to the advancement of smart vibration control technologies, offering potential applications in predictive maintenance, structural diagnostics, and industrial automation.
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