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In the presence of 150+ computer systems, modern spectrum analyzers, and 23+ digital software such as Cadence and Kiel, you are open to test and work in a learning environment that transforms your practical skills into valuable experience for the future. The devices, equipment, machines and other physical resources used in our Labs and classrooms are top-notch, and frequently upgraded. Some of the popular Labs that students work at, during their course:
In the Analog Electronics Lab, students explore the foundational principles of electronic design in the domain Analog Circuits, gaining hands-on experience in constructing and analyzing component-level circuits. They work with circuits such as amplifiers, comparators using IC741, and Various pulse generator circuits using the timer IC 555 etc., while utilizing advanced testing equipment like Digital Storage Oscilloscopes (DSOs), Cathode Ray Oscilloscope (CROs), Spectrum Analysers, Multimeters, and IC testers. This practical exposure bridges theoretical knowledge with real-world application, fostering essential problem-solving and logical reasoning skills in analog design, and equipping students to tackle future challenges in the field of electronics engineering for VLSI Design.
The hardware lab facility for the course “Analysis and Design of Digital Circuits” is designed to provide VLSI students with hands-on experience in designing and implementing digital circuits. The lab is equipped with digital logic trainer kits, breadboards, and comprehensive component kits, allowing students to build and test various combinational and sequential circuits. A wide range of discrete components and ICs, including 7400 series logic ICs, flip-flops, multiplexers, are provided for circuit customization. Students perform experiments on fundamental and advanced digital circuits, such as adders, decoders, shift registers, and FSMs, enabling them to bridge theoretical knowledge with practical applications. This state-of-the-art hardware lab creates a conducive environment for mastering digital circuit design and fostering innovation in VLSI technology.
The Physics of Semiconductor laboratory course provides students with practical experience in analyzing semiconductor devices, focusing on PN junction diodes, MOSFETs, zener diodes, LEDs, and photodiodes. By analysing the experimental outcome, students gain a deep understanding of semiconductor behavior in real-world scenarios. The course bridges theoretical knowledge with hands-on applications, fostering critical thinking and problem-solving skills. This prepares students to tackle challenges in semiconductor technology, ensuring they are academically strong and industry-ready in electronics and device design.
The Verilog HDL Laboratory equips students with hands-on experience in digital design and hardware description languages, focusing on Verilog HDL. This lab bridges the gap between theoretical concepts and real-world applications, preparing students for careers in VLSI design for chip design in the application of AI accelerators, embedded systems, and Control Units. With laboratory training on industry-standard tools like AMD-Xilinx Vivado and implementation on FPGA platforms, students learn design, verification, implementation, and real time testing of digital systems. The lab emphasizes practical applications, enabling students to gain industry-relevant skills and excel in core engineering roles.
The MATLAB lab for the course “Network Theory” is designed to provide VLSI students with a robust platform to analyze, simulate, and visualize complex electrical network. The objective of this lab is to analyze and simulate electrical circuits using MATLAB Simulink, focusing on circuit responses for DC and AC networks, transient analysis, and network theorems. MATLAB Simulink and Simscape Electrical are utilized for this purpose.
Throughout the lab, students record simulated waveforms, voltage/current values, and validate results with theoretical calculations. A comparison between experimental and theoretical findings is encouraged to deepen understanding. The conclusion summarizes key observations, discussing the effectiveness of MATLAB Simulink in analyzing circuit behavior and enhancing comprehension of fundamental network theories. This lab provides a structured and hands-on approach to Network Theory using MATLAB Simulink.
The Embedded Systems Laboratory offers students practical experience in programming and interfacing ARM microcontrollers using the KEIL software. This lab focuses on developing Assembly language programs that enhance understanding of low-level hardware control and real-time applications. Through structured experiments, students learn to manipulate registers, configure GPIOs, implement delay loops, and manage interrupts—all within a simulated environment. These hands-on exercises build a strong foundation in embedded system development, essential for careers in IoT, robotics, and embedded automation.
The Signals and Systems Laboratory provides hands-on experience in analyzing and processing signals using MATLAB. Students engage in experiments that cover concepts such as convolution, system response, Fourier and Laplace transforms, and filter design. Through visual simulations and coding, they learn how to model continuous and discrete-time systems, explore frequency domain analysis, and apply theoretical principles to practical scenarios. This lab enhances conceptual clarity and equips students with essential skills for advanced signal processing and communication systems.
The Scripting Language for VLSI Laboratory is designed to introduce students to the power of Python for automating VLSI design workflows. In this lab, students develop scripts that assist in parsing hardware description languages, generating testbenches, analysing simulation data, and optimising design processes. Through a series of hands-on experiments, they gain proficiency in using Python libraries and tools relevant to electronic design automation (EDA), enabling faster and more efficient design verification. This experience equips students with essential programming skills that are increasingly vital in the semiconductor and VLSI industries.
The VLSI Digital Design Laboratory provides students with industry-relevant training using Cadence design tools. This lab focuses on digital circuit implementation through HDL-based design, simulation, synthesis, and verification. Students gain hands-on experience in creating combinational and sequential logic circuits, analysing timing parameters, and optimising layouts using Cadence’s integrated suite. Through practical sessions, learners build confidence in FPGA prototyping and design flow management, preparing them for careers in ASIC and SoC development.
The System Verilog Laboratory immerses students in advanced digital design and verification techniques using industry-standard Cadence tools. This lab focuses on modelling, simulation, and verification of complex digital systems through System Verilog constructs such as interfaces, assertions, and constrained random testing. Students gain hands-on experience in writing testbenches, applying verification methodologies, and debugging functional designs. The use of Cadence’s integrated environment enables learners to simulate real-world scenarios and validate designs efficiently, preparing them for roles in VLSI verification and ASIC development.
The Analog VLSI Design Laboratory offers hands-on training in designing and analysing analog circuits using Cadence EDA tools. Students work on creating building blocks such as amplifiers, comparators, and current mirrors, while learning techniques like biasing, layout design, and post-layout simulation. Through practical exercises, they explore challenges unique to analog design—including noise, matching, and parasitics—within the Cadence Virtuoso platform. This lab experience equips students with essential skills for analog and mixed-signal IC development, aligning them with industry practices in semiconductor design.
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MVJ College of Engineering, Near ITPB, Whitefield, Bangalore-560 067