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NVH Learning Lab

An Initiative by Flora Education Society,

Supported by La Fondation Dassault Systemes

Fundamentals of Low Frequency NVH and Automotive Applications

A course developed by Dr. Mohan Godse for Flora Education Society and supported by La Fondation Dassault Systemes

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Faculty Development Programme (FDP)

Our FDPs are designed to create a vibrant ecosystem connecting colleges, faculty, and industry experts to cultivate the next generation of engineers ready for real-world challenges.

Advanced Curriculum

Providing an industry-aligned curriculum on NVH fundamentals and applications.

Industry-Academia Bridge

Connecting faculty with industry leaders through live projects and expert sessions.

Hands-On Learning

Emphasizing practical skills with live demos on our state-of-the-art NVH Learning Lab equipment.

Our FDP Initiatives

On Fundamentals of Low Frequency NVH and Automotive Applications

The FDP aims to create an ecosystem of colleges, faculty, and industry for the development of learners in colleges to work on industrial projects. It will lead to solving industrial problems and the development of new technologies.

Three years of effort from La Fondation Dassault Systèmes, Dr. Godse, and Flora Institutes resulted in the creation of the course "Fundamentals of Low Frequency NVH & Automotive Applications" and the NVH Learning Laboratory. The development of the course content is also a fruit of this initiative.

Past & Present Programmes
  • Initial FDP (2023): The foundational FDP was conducted at Dassault Systèmes, Pune, with 12 faculty members from 4 engineering colleges participating.
  • First FDP (Dec 2024): Conducted for faculty from Ramdeobaba College of Engineering (Nagpur), BMS College of Engineering (Bengaluru), Dayanand Sagar College of Engineering (Bengaluru), and KLS Gogte Institute of Technology (Belgaum).
  • Second FDP (Mar 2024): Hosted at Dayanand Sagar University, Bengaluru, with 20 participants from various institutions including KLS Institute of Technology (Hubali) and Amrita Vishwa Vidyapeetham (Bengaluru).
  • Third FDP (June 2025): Currently underway at Flora Institute of Technology, Pune for institutes in and around the city, with participation from Walchand College of Engineering (Sangli), COEP, VIT, PCCOE, and many others.
Industry Collaboration & Impact

A key aspect of our FDPs is strong industry engagement:

  • Expert Sessions: Resource person Dr. Mohan Godse interacted with participants on real-world NVH applications, FEA formulation, and experimental techniques.
  • Industry Insights: Senior NVH consultants from Mahesh Software shared fundamentals on measurements for automotive and non-automotive applications.
  • Live Projects: Mr. Vinod Hipparge from Tata Motors shared live vehicle vibration problems and offered 10 projects for students and faculty. Following the FDP, 50 final year students will be trained and assigned these projects.
  • Live Demonstrations: Mr. Prasad Ghorpade from Aimil Limited presented dynamic unbalance with live demonstrations using a DAQ system on our NVH Learning Lab.
Future Vision

Three further FDPs are planned to expand our ecosystem to engineering colleges in Northern, Southern, and Eastern India, continuing our mission to bridge the gap between academia and industry.

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Faculty Development Programme (FDP Gallery)

A glimpse into our state-of-the-art facilities and hands-on sessions.

A detailed 3D rendering of a futuristic car design
Half car test rig in the lab
Half car test rig in the lab
Inauguration event for the lab
A hands-on lab session with students
Vibration isolation test rig
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor
A close-up of a DIY Arduino-based accelerometer sensor

Vehicle Attributes & NVH Integration

Explore how Noise, Vibration, and Harshness (NVH) is intricately linked with various critical vehicle attributes, ensuring optimal performance, comfort, and safety.

NVH
Styling & Ergonomics
Aerodynamics
Vehicle Dynamics
Connected Vehicle
Safety & Emission
Durability
Embedded Systems
Thermal Management
Cost, Weight, & Fuel Economy
Power & Control System
Integration

Our Partnership Ecosystem

A collaborative network driving innovation in Noise, Vibration, and Harshness (NVH) education and research.

Automotive
Aerospace
Civil
Electronics

Noise, Vibration, and Harshness (NVH)

Customer expectations and regulatory requirements (EHS)

Dr. Mohan Godse (Subject Expert)
Flora Education Society
La Fondation Dassault Systemes Fondation
Academic Institutes
NVH Industry Experts

NVH Elective: "Fundamentals of low frequency NVH & automotive applications"

Industry Ready Workforce
Faculty Development Program

About the Course

Developing an industry-ready workforce with knowledge and skills in the NVH domain.

Why NVH?

There is an increasing focus on Noise, Vibration, and Harshness (NVH) in product design and development to:

  • Achieve comfort and performance
  • Meet EHS requirements
  • Eliminate vibration-based failures and reduce down time of assets

Objectives

  • Bridge the gap between the university and industry by developing one semester long NVH course for B.Tech. & M.Tech. students
  • Teach fundamentals of NVH & FEA-based NVH simulations to provide design solutions
  • Develop a library of Abaqus models to simulate NVH behavior of a car
  • Develop NVH Learning Lab and an NVH center of excellence

Expected Outcomes

This course aims to:

  • Provide comprehensive overview of NVH fundamentals and introduction to FEA-based NVH theory & simulations
  • Learn NVH phenomenon through experimentation
  • Develop an NVH center of excellence
Close-up of a modern car engine bay highlighting complex components

Applications of NVH

NVH principles are critical across a wide range of industries.

Automotive engineer working on a car
NVH
Airplane flying in the sky
BIW
A modern high-speed train on a track
Vande Bharat
Wind turbines in a field at sunset
Power transmission
A modern bridge with complex architecture
Rafael
High-voltage power lines against a clear sky
Windmill

Course Details

A comprehensive overview of our one-semester elective course.

Course Overview

One semester long NVH elective course for B.Tech./M.Tech. students, as per AICTE guidelines.

Prerequisite:

Vibration analysis & FEA

Lab Sessions

  • Abaqus simulations example library
  • NVH Learning Lab experiments
A mechanical engineering test rig for automotive parts
Half Car Test Rig
A smaller, focused test rig for a single car suspension
Quarter Car Test Rig & Vibration Isolation Rig

Pioneering Progress: NVH Elective Implementation Status

Sr. No. College Location Students Empowered Faculty Transformed
B. Tech. M. Tech.
1 KLS Gogte Institute of Technology Belagavi, Karnataka 27** 16 11*+
2 Dayananda Sagar University Bengaluru, Karnataka 55** 7++
3 RCOEM Nagpur, Maharashtra 18 3++
4 BMS College of Engineering Bengaluru, Karnataka 8 3
Subtotal 100 22 24
Total 146

** Mechanical Engineering plus aerospace engineering

++ Includes faculty members from KLSIT, MSRIT, Bengaluru, AVV, Bengaluru

*+ Mechanical, structural, and civil engineering, Hubli

Detailed NVH Course Content

A comprehensive look at the curriculum of our specialized NVH elective course.

Course Outline: M.Tech. (Mech.), BMS College, Bengaluru

Course Name Code Credits Marks
L T P CIE SEE
Fundamentals of NVH and its Applications 22MEMDPENV 3 0 0 50 50
Prerequisite

Dynamics of Machinery, Modeling & Finite Element Analysis

Course Outline: M.Tech. (Mech.), BMS College, Bengaluru

Unit Topic
Unit 1 NVH fundamentals
Unit 2 Finite Element Formulation: 1D
Unit 3 Finite Element Formulation: 2D
Unit 4 Dynamic Response Analysis Damping
Unit 5 Experimental and Numerical Modal Analysis
NVH Faculty Development Program: June 23rd-27th, '23, Pune

This program was designed for colleges who have agreed to offer the NVH course as part of their curriculum in the 2023 Academic year.

  • One-week residential program: 12 professors from 4 colleges attended the workshop.
  • Trained professors to deliver a one-semester course on NVH with hands-on, exercise-based, simulation-driven what-if analysis oriented, and industry-oriented content.

The Faculty Development Program (FDP) was conducted by Dr. Mohan Godse (Creator of NVH course) along with 3DS domain experts, transforming the way we learn and discover.

NVH Faculty Development Program Group Photo and Activities
NVH FDP & Elective at KLS GIT, Belagavi, '24

Faculty Development Program and student training program for NVH was conducted at KLS Gogte Institute of Technology, Belagavi between Jan 16th - 19th, '24.

  • Four days residential program: 11 professors and 19 M.Tech. (Civil) students were trained.
  • NVH elective course is offered to 8 M.Tech. (Mechanical) students by Prof. Kiran Kattimani and Prof. Ranganath Avadhani.
  • Delivered hands-on, exercise-based, simulation-driven industry-oriented course.

The FDP was conducted by Dr. Mohan Godse. The course was offered by Prof. Kiran Kattimani and Prof. Ranganath Avadhani.

NVH FDP & Elective at KLS GIT, Belagavi
NVH Elective at Dayanand Sagar University, Bengaluru, 2023

NVH elective was offered at Dayanand Sagar University in 2023.

  • A total of 31 B.Tech. (Mech.) students were trained in 2023 by Prof. Dr. Rammohan Bhanumurthy and Prof. Dr. Vishwanathan R.
  • Hands-on training on NVH theory, Abaqus simulations, along with real-world case studies were presented to the students.

The course was offered by Dr. Rammohan Bhanurmurthy and Prof. Vishwanathan R.

NVH elective at Dayanand Sagar University, Bengaluru, 2023
NVH Elective Course at RCOEM, Nagpur for B.Tech. (Mech.), '23

Eighteen B.Tech. (Mechanical) students from RCOEM, Nagpur completed the NVH elective course in 2023.

  • Prof. Dr. Nikhade & Prof. Dr. Jha, RCOEM, Nagpur delivered hands-on, simulation-driven, what-if analysis oriented, and industry-oriented course for a full semester in 2023.

The course was offered by Prof. Dr. G.R. Nikhade and Prof. Dr. A.K. Jha, RCOEM, Nagpur.

NVH elective course at RCOEM, Nagpur for B.Tech. (Mech.), '23
NVH Elective at BMS College of Engineering, Bengaluru

Eight M.Tech. (Mechanical) students enrolled in the NVH elective course in 2024.

  • M.Tech. students are being trained by Prof. Dr. Shivashankar R. Srivatsa.
  • Hands-on training on NVH theory, Abaqus simulations, along with real-world case studies are being presented to the students.

The course was offered by Dr. Shivashankar R. Srivatsa.

NVH elective at BMS College of Engineering, Bengaluru
NVH consulting & training at M/s Varroc Tech Center, Pune, 2024
  • Provided consulting & training for vibration analysis, for a global Tier 1 supplier at Pune
  • Trained over 15 engineers in NVH domain and provided consulting services to address vibration based fatigue failures.
  • Customer feedback (CoC Head): “Thank You! It was a valuable and a useful NVH session with you. We could learn few things newly and could get directions for achieving First Time Right (FTR).”

Senior Consultant Dr. Mohan Godse

NVH elective at BMS College of Engineering, Bengaluru
Unit 1: Advanced NVH Fundamentals and Signal Processing
  • Fundamental assumptions in low amplitude linear vs. non-linear NVH analysis
  • Maxwell-Betti reciprocal theorem and its implications in structural dynamics
  • Principal mass moment of inertia and radius of gyration: deeper dive into rotational dynamics
  • Kinematic relationship between vehicle speed, road excitation frequency, and tire non-uniformities
  • Classification and characteristics of various NVH loads: steady-state, transient, and random excitations
  • Order analysis and its application in rotating machinery NVH
  • Advanced signal metrics: RMS, average value, peak factor, crest factor, and their significance
  • Sound pressure levels in decibels, sound intensity, and sound power concepts
  • Propagation of transverse and longitudinal sound waves in various media
  • Detailed analysis of octave bands, fractional octave bands, and spectral analysis techniques
  • Superposition principle for combining sound pressure from multiple uncorrelated and correlated sources
  • Comprehensive psychoacoustics: human ear physiology, absolute threshold of hearing, A-B-C-D weighting curves, loudness perception, sharpness, roughness, and other sound quality metrics
  • Time domain vs. frequency domain analysis: Fourier Series, Fourier Transform, Fast Fourier Transform (FFT), Discrete Fourier Transform (DFT)
  • Complex numbers and Euler's formula in vibration analysis, including interpretation of amplitude and phase spectra
  • Introduction to advanced signal processing concepts: windowing techniques (Hanning, Flat Top), aliasing, leakage, and coherence functions
Unit 2: Advanced Finite Element Formulation: 1D Structural Elements
  • Variational principles: Hamilton's principle and its derivation from Lagrangian mechanics, Principle of minimum potential energy for static and dynamic systems
  • Stress, strain, and equilibrium equations in continuous media, including generalized Hooke's Law for isotropic and anisotropic materials
  • Detailed strain-displacement and stress-strain relationships for 1D elements (bar, truss, beam)
  • Special cases of 1D problems: varying cross-section, stepped bars, and composite beams
  • Natural coordinate system and shape functions for linear and higher-order 1D elements (e.g., cubic Hermite for beams)
  • Derivation of element and global stiffness & mass matrices for 1D & 2D spring, truss, and beam elements using direct stiffness method and variational approaches
  • Eigenvalues and eigenvectors: physical interpretation as natural frequencies and mode shapes, their mathematical properties (orthogonality)
  • Real eigenvalue problem formulation and solution methods for undamped free vibration
  • Orthogonal properties of eigenvectors with respect to mass and stiffness matrices
  • Rayleigh quotient and its application in approximating natural frequencies and bounding eigenvalues
  • Generalized mass, stiffness, and force vector in modal coordinates
  • Comparison of consistent mass matrix (derived from shape functions) and lumped mass matrix (diagonalization), and their effects on accuracy and computational efficiency
  • Rigid body modes: identification, interpretation, and handling in FE models
  • Detailed analysis of harmonic loads: representation of wheel unbalance, speed breakers, and engine unbalance as sinusoidal forcing functions
  • Introduction to damping modeling in FEA: viscous, structural, and Rayleigh damping models for 1D systems.
Unit 3: Advanced Finite Element Formulation: 2D Continua
  • Extension of spring elements to 2D systems, illustrating fundamental concepts of multi-dimensional stiffness
  • Constant Strain Triangle (CST) element: derivation of shape functions, strain-displacement matrix, and stiffness matrix; advantages and limitations
  • Isoparametric formulation for quadrilateral elements: linear (Q4) and quadratic (Q8/Q9) elements
  • Concepts of Jacobian matrix, inverse Jacobian, and numerical integration (Gauss Quadrature) for isoparametric elements
  • Formulation of element stiffness and mass matrices for 2D continuum elements (CST, Q4, Q8)
  • Treatment of boundary conditions (Dirichlet and Neumann) in 2D FE models
  • Detailed problems and case studies applying 2D elements to:
    • Plane stress and plane strain analyses
    • Thermal stress analysis
    • Steady-state heat transfer problems
    • Basic dynamic analyses similar to Unit-2 (eigenvalue extraction, harmonic response)
  • Introduction to higher-order 2D elements and their advantages in capturing complex stress distributions
  • Consideration of mesh quality metrics (aspect ratio, skewness, Jacobian ratio) and their impact on FEA accuracy for 2D meshes
Unit 4: Advanced Dynamic Response Analysis and Damping Models
  • Comprehensive study of damping models:
    • Modal damping: definition, determination from experimental data, and application in modal analysis
    • Rayleigh Damping (proportional damping): alpha and beta damping coefficients, frequency dependency
    • Structural damping (hysteretic damping): definition and implementation in frequency response analysis
    • Non-linear damping phenomena and their approximate modeling approaches
  • Advanced mathematical modeling of elastomers and viscoelastic materials:
    • Frequency-dependent static and dynamic stiffness characteristics
    • Complex modulus and loss factor representation
    • Viscoelastic constitutive models (e.g., Maxwell, Voigt, Zener models)
  • Forced dynamic response analyses:
    • Forced Harmonic Response: detailed theory and computational methods (frequency domain analysis)
    • Transient Dynamic Response: analysis of time-varying loads, impulse response, step response
  • Solution methods for forced dynamic analyses:
    • Mode Superposition Method: theoretical basis, computational efficiency, criteria for mode truncation, handling rigid body modes
    • Direct Integration Methods: Newmark-beta method, Wilson-$\theta$ method, their stability and accuracy considerations
  • Physical coordinates vs. modal coordinates: transformation, advantages, and limitations of each representation
  • Modal mass, modal stiffness, and modal force: definition and interpretation in the context of uncoupled modal equations
  • Concepts of cut-off frequency for effective solution of low frequency NVH problems
  • Nyquist rule (Shannon-Nyquist sampling theorem) and its critical importance in digital signal processing for vibration measurements
  • Introduction to Random Vibration Analysis: Power Spectral Density (PSD), RMS values, and statistical interpretation for broadband random inputs.
Unit 5: Advanced Experimental and Numerical Modal Analysis
  • In-depth determination of natural frequencies, mode shapes, and modal damping factors from experimental data
  • Modal testing techniques:
    • Experimental Modal Analysis (EMA): procedures, instrumentation (accelerometers, load cells), excitation methods (impact hammer, shakers - random, swept sine, burst random)
    • Operational Modal Analysis (OMA): output-only modal analysis, techniques (e.g., SSI, FDD) and applications in operating conditions
    • Adherence to relevant international standards (e.g., ISO, SAE) for modal testing setup and analysis
  • Frequency Response Functions (FRFs):
    • Theoretical background and different types of FRFs ($H_1, H_2, H_v, H_a$)
    • Methods for FRF estimation from input/output measurements
    • Interpretation of FRF plots for resonance and anti-resonance identification
  • Modal data acquisition and measurements: transducer selection, signal conditioning, data logging, and pre-processing
  • Advanced Dynamic FE Analyses:
    • Eigenvalue solution methods: direct solvers (e.g., Lanczos, Subspace Iteration) and iterative solvers (e.g., Block Lanczos) for large-scale FE models
    • Frequency extraction techniques in commercial FEA software
  • Modal assurance criterion (MAC): theory, calculation, and application for correlating experimental and numerical mode shapes, model updating strategies (sensitivity-based, optimization-based)
  • Advanced Application Case Studies in Automotive NVH:
    • Steady-state dynamics: analysis of forced vibrations under continuous harmonic excitation (e.g., engine-induced vibrations, road noise)
    • Modal transient response analysis for impact and impulse loads (e.g., road bump response, door slam)
    • Base motion excitation analysis: structural response to prescribed displacements or accelerations (e.g., seismic excitation, vehicle body response to suspension input)
    • Brake squeal analysis: advanced computational methods for predicting and mitigating friction-induced instabilities
    • Coupled structural-acoustic analysis: theoretical framework for vibro-acoustic coupling, methods (e.g., direct FEM-BEM, modal superposition), applications in interior noise prediction and sound package optimization
    • Applications of topology and sizing optimization techniques for automotive problems, including lightweighting with NVH performance constraints
Advanced Topics and Case Studies
NVH Course Development and Deployment

Hands-on sessions are crucial for practical understanding of NVH concepts using advanced software like Abaqus.

Advanced 1-DOF, 2-DOF, 4-DOF, Door, and BIW Models
Advanced representation of 1-DOF, 2-DOF, 4-DOF, Door, and BIW models for NVH analysis

Advanced Transient Dynamic Analysis & Ground Motion
Illustration of transient dynamic analysis of a car over speed bumps and an overhead water tank subjected to ground motion

Advanced Earthquake Proof Buildings and Optimization
Advanced Earthquake Proof Buildings and Optimization

Advanced Comparison of Abaqus Simulation Results with a Car Roof
Advanced Comparison of Abaqus Simulation Results with a Car Roof

Hands-on-session: Beat phenomenon (vibration)
Practical, Industry-Oriented Course Delivery

Pedagogy and Advanced Learning Flow
Advanced Learning Flow
Real World
Optimization
Math model
Hand calculation / Finite
Element Simulations /
MATLAB or SciLab simulation
Results interpretation
Lab & on road
validation
Half car test rig

Half car test rig

Lab validation spectrum

Lab validation

Suspension tracked by LED lights

Suspension tracked by LED lights

Mathematical model of a car

Mathematical model

Abaqus Simulation

Abaqus Simulation

This flowchart illustrates our advanced pedagogical approach, integrating real-world problem-solving, optimization, mathematical modeling, and validation through both simulations and physical lab/on-road testing. This cyclical process ensures a comprehensive and practical learning experience for students, leading to robust results interpretation and continuous improvement.

Textbooks and Reference Books
Textbook: Introduction to Finite Elements in Engineering

Introduction to Finite Elements in Engineering

Tirupathi R. Chandrupatla, Ashok D. Belegundu

Textbook: Textbook of Finite Element Analysis

Textbook of Finite Element Analysis

P. Seshu

Textbook: Theory of Vibrations with Applications

Theory of Vibrations with Applications

W.T. Thomson, Marie Dillon Dahleh, Chandramouli Padmanabhan

Textbook: Fundamentals of Acoustics

Fundamentals of Acoustics

Lawrence E. Kinsler, Austin R. Frey, Alan B. Coppens, James V. Sanders

NVH Centre of Excellence (CoE) Roadmap

Our strategic plan to develop a world-class NVH Centre of Excellence, fostering innovation and industry readiness.

Phase 1

One semester long NVH elective course for mechanical / civil / aeronautical engineering (Deployed in June '23)

Phase 2

"NVH learning lab - Phase I" (Inaugurated on Dec. 20th, '23)

Phase 3

"NVH Learning Lab - Phase II": Data acquisition and diagnostic lab (Proposed)

NVH Elective Course Deployment: A Holistic Approach

Our NVH elective course is designed for maximum impact, integrating advanced theory with practical, industry-oriented learning experiences.

Faculty Empowerment

  • A total of 20 faculty members from GIT, BMS, DSU, and RCOEM have been rigorously trained by Dr. Mohan Godse, the esteemed developer of our NVH curriculum and training content.
  • This Faculty Development Program (FDP) was expertly conducted by Dr. Mohan Godse, alongside cutting-edge 3DS domain experts, ensuring a world-class learning experience.

Student Readiness

  • Over 80 B.Tech. & M.Tech. students have been empowered with critical NVH knowledge and skills, trained directly by the professors at GIT, BMS, DSU, and RCOEM.
  • The NVH elective stands out as a hands-on, exercise-based, simulation-driven, and experimental-based industry-oriented course, preparing students for real-world challenges.
A professional training session in a modern office Collaborative learning environment with students and laptops University lecture hall with students listening to a professor Engineering students working together on a project

NVH Learning Lab – Inauguration Event

Relive the memorable moments from the grand inauguration of our state-of-the-art NVH Learning Lab on December 20th, 2023.

A group of people at a ribbon-cutting ceremony for a new facility

The Inauguration Ceremony

Dignitaries and guests posing for a photo at an event

Key Dignitaries and Guests

A person demonstrating equipment to a group of interested people

Live Lab Demonstrations

People networking and discussing during an event

Engaging Discussions and Interactive Sessions

People networking and discussing during an event

Live Lab Demonstrations

People networking and discussing during an event

NVH Learning Lab

Explore the various test rigs and DIY solutions available in our cutting-edge NVH Learning Lab, designed for hands-on learning and practical application.

NVH Learning Lab

NVH Learning Lab equipped with modern test rigs and analysis tools.

Process of Shortlisting Engineering Colleges

Discover the rigorous process we undertake to identify and partner with top engineering colleges across India, ensuring quality education and industry alignment.

Map of India showing colleges approached and shortlisted

Colleges Approached & Shortlisted by State

State Approached Shortlisted
Rajasthan 1 -
Maharashtra 8 1
Karnataka 3 3
Tamil Nadu 1 1
Andhra Pradesh 1 -
Total 14 4

Shortlisted Colleges

  • KLS GIT, Belagavi, Karnataka
  • DSU, Bengaluru, Karnataka
  • RCOEM, Nagpur, Maharashtra
  • BMS, Bengaluru, Karnataka

Voices of Success

What our partners and students say about the program.

"Noise, Vibration, and Harshness (NVH) is a crucial elective... This course strongly equips students with the analytical skills and hands-on experience to address real-world challenges..."

Dr. Harshit B. Kulkarni

HOD, Mechanical Engineering Dept., KLS GIT, Belagavi

"Thank You! It was a valuable and a useful NVH session with you. We could learn few things newly and could get directions for achieving First Time Right (FTR)."

Mr. Sandeep Rane

CoC Head, Varroc Technical Center, Pune