IN-2025-C1407-MU
Location
India
Internship type
ON-SITE
Reference number
IN-2025-C1407-MU
General discipline
Electrical Engineering
Electronics Engineering
Mathematics and Statistics
Completed Years of Study
2
Fields of Study
Languages
English Excellent (C1, C2)
Required Knowledge and Experience
-
Other Requirements
-
Duration
8 - 12 Weeks
Within These Dates
01.06.2025 - 30.11.2025
Holidays
NONE
Work Environment
-
Gross pay
7000 INR / month
Working Hours
40.0 per week / 8.0 per day
Type of Accommoditation
IAESTE India LC Manipal
Cost of lodging
-
Cost of living
4500 INR / month
Additional Info
The option of Work from Home is available for this offer. In the case where the intern chooses to work from home, there will be no stipend provided. However, in the case where the intern opts to intern at the employer's address, a stipend will be provided for the period of internship.
Work description
Project Title: Low-Frequency Active Vibration Isolation System for Precision EquipmentDetailed Project Description: Low-frequency vibrations present a significant challenge in various industrial and research settings, impacting the performance and accuracy of precision equipment. Traditional passive vibration isolation systems are ineffective in addressing low-frequency vibrations. In contrast, active vibration isolation systems can actively counteract these vibrations, ensuring stable and precise operation of sensitive equipment. The project aims to design, develop, and implement a Low-Frequency Active Vibration Isolation System for precision equipment. The system will utilize advanced control algorithms and sensors to actively mitigate low-frequency vibrations, ensuring optimal performance and accuracy of sensitive equipment. The system will include low-frequency vibration sensors to detect vibrations in the target frequency range, actuators to generate counteracting vibrations to cancel out detected low-frequency vibrations, and a sophisticated control unit to process sensor data and control the actuators effectively.Outcomes of the Project:In-depth understanding of the dynamics of vibration isolation systems.In-depth understanding of the control of vibration isolation systems.Review of existing methodologies and exploration of advanced methods.Development of key numerical modeling skills required for system modeling.Analysis of system performance using MATLAB/Simscape.Expected Results: Mathematical model and control algorithms for active vibration isolation systems.
Deadline
06.01.2025