18NTL67: Mems Simulation Lab Nano Syllabus for BE 6th Sem 2018 Scheme VTU

Mems Simulation Lab detailed Syllabus for Nano Technology (Nano), 2018 scheme has been taken from the VTUs official website and presented for the VTU students. For Course Code, Subject Names, Teaching Department, Paper Setting Board, Theory Lectures, Tutorial, Practical/Drawing, Duration in Hours, CIE Marks, Total Marks, Credits and other information do visit full semester subjects post given below. The Syllabus PDF files can also be downloaded from the official website of the university.

For all other VTU Nano 6th Sem Syllabus for BE 2018 Scheme, do visit VTU Nano 6th Sem Syllabus for BE 2018 Scheme Subjects. The detailed Syllabus for mems simulation lab is as follows.

Course Learning Objectives:

For the complete Syllabus, results, class timetable, and many other features kindly download the iStudy App
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Experiments

1. Calculation & Simulation of burst pressure, non-linearity & plot graph for sensitivity for Piezoresitive pressure sensor with a
   1. square diaphragm,
   2. round diaphragm,
   3. rectangular diaphragm.
2. Calculation & Simulation of maximum acceleration, maximum sensitivity, non-linearity & plot graph for acceleration V/S displacement of capacitive accelerometer for static signal.
3. Calculation & Simulation of
   1. maximum acceleration, maximum displacement & plot graph for acceleration V/S displacement of capacitive accelerometer for step signal,
   2. time duration of pulse & plot graph for acceleration V/S time of capacitive accelerometer for pulse signal,
   3. output current, output voltage, piezoelectric capacitance & plot graph for output V/S frequency of piezoelectric accelerometer under longitudinal load.
4. Calculation & Simulation of
   1. output current, output voltage, piezoelectric capacitance & plot graph for output V/S frequency of thin film based piezoelectric accelerometer,
   2. pull in voltage, actuation force, balanced displacement & plot graph for force V/S displacement of parallel plate actuator for normal
5. Calculation & Smulation of
   1. balanced displacement, actuation force, normal spring constant & plot graph for voltage V/S displacement of comb drive actuator for lateral motion,
   2. tip deflection, tip force & plot graph for deflection V/S film thickness of cantilever based bimetallic thermal actuator,
   3. deflection, tip force & plot graph for deflection V/S beam length of thermal bimorph actuator
6. Calculation & Simulation of maximum deflection, response time, maximum temperature change & plot graph for transient response of thermal bent beam actuator.
7. Calculation & Simulation of
   1. actuator displacement, actuator force, electric field strength & plot graph for actuator force of longitudinal piezoelectric actuator,
   2. actuator displacement, actuator force, electric field strength & plot graph for actuator displacement of transverse piezoelectric actuator.
8. Using QuantumWise – Virtual NanoLab Software
   1. Modelling metal-semiconductor contacts: The Ag-Si interface,
   2. Resistivity calculations using the MD-Landauer method,
   3. Spin-orbit transport calculations: Bi2Se3 topological insulator thin-film device,
   4. Opening a band gap in silicene and bilayer graphene with an electric field
9. Using QuantumWise – Virtual NanoLab Software
   1. Building molecule-surface systems: Benzene on Au (111),
   2. Spin-dependent Bloch states in graphene nanoribbons,
   3. Exploring graphene – Build a graphene sheet – Build a CNT – Transmission spectrum of a GNR,
   4. Twisted nanoribbon -Transmission spectrum – Buckling a graphene sheet
10. Sequence retrieval from nucleic acid and protein data base using NCBI, Multiple alignment of sequence and pattern determination by NCBI and Clustal Omega Prosite software
11. Evolutionary studies / phylogenetic analysis by phylowin software and Visualization by TreeView software; Secondary structure prediction of proteins by Sopma software
12. Identification of functional sites in gene / genome by Gen Sean and ORF finder software; Super imposition of molecular structures and calculation of RMSD by SPDBV software; PDB structure retrieval and visualization; analysis of homologous structure by RASMOL software

Course Outcomes:

At the end of the course the student will be able to:

• Understand the simulation programmes for the MEMS characteristics.
• Study about MEMS devices and calculations by using MEMSolver software.
• The simulation at atomic and molecular level by using softwares.
• About the nucleic acids, proteins, superimposition of molecules and building the phylogenetic tree.

Conduct of Practical Examination:

For the complete Syllabus, results, class timetable, and many other features kindly download the iStudy App
It is a lightweight, easy to use, no images, and no pdfs platform to make students’s lives easier.
.

For detail Syllabus of all other subjects of BE 6th Sem Nano Technology, visit (Nano) 6th Sem Syllabus Subjects.

For all (CBSE & Non-CBSC) BE results, visit VTU BE all semester results direct links.