Past Present and Future of Integrated Circuits

Introduction to VLSI
Classification of ICs
Design Flow (Y-Map)
Fabrication Process
  VLSI Components and Architectures

Bipolar Technologies
  MOS Transistor Theory

Delays

Power (static , dynamic power)

ASIC VS FPGAs
Types of Integrated Circuits
Switch/Transistor Level Circuit Design
MOS, NMOS, PMOS, CMOS
Gate Level Design
   Combinational Logic Circuits
RTL (Register Transfer Level Design)
   Multiplexer, Encoder, Decoder,  State Machine, Orbiter and Scheduler
Abstract Level Design
Tools:  ROCCC, C2HDL LEGUP, Vivado, Quartus, Modelsim

Processor and Memory
Components: ALU, Buses, Registers etc.


System on Chip Design I
Using processors, caches, buses etc.

System on Chip Design II
Multi Processor System Design

Basic Circuits Design Concept

Ultra-Fast VLSI Circuits and System and their Design
Gallium arsenide, Graphene etc.
Ultra-Fast VLSI Circuits and System and their Design
3D Fabrication
Ultra-Fast VLSI Circuits and System and their Design
3D FPGA i.e Tabaula etc
Analog Circuit Design (Field Programmable Analog Arrays) FPAA
 
Dr. Tassadaq Hussain is the head of workshop organizing committee.

He is a permanent faculty member at, Riphah International University.
He did his Ph.D. from Barcelona-tech Spain, in collaboration with Barcelona Supercomputing Center and Microsoft Research Center.

He has more than 12 years of industrial experience including,    Infineon technology France, Microsoft Research Cambridge, PLDA Italia, IBM Zurich Switzerland, and REPSOL Spain.
He has more than 35 international publications and filed two patents.
Currently, he is working on artificial intelligence and supercomputing, Software Define Radios, Embedded Computer Vision, high performance signal processing, and, parallel programming.

Very Large Scale integration (VLSI) Design

UCERD Rawalpindi
UCERD Islamabad
UCERD Murree
VLSI Design course emphasizes on imparting overall exposure to the concept and design methodologies of all significant aspects of VLSI engineering relevant to the industry needs. The program offers in-depth, hands-on training on various design methods such as gate level, register transfer level, abstract level designs, etc. At the end of the course, the student can understand the VLSI manufacturing processor, solve a real-world problems and map and port these issues in an integrated circuit.
At the end of my course, students should learn:
To identify the Physical Layout and Gate Level System Design using 65 nm ASIC technology.
To discuss a scalar RISC core and Application-Specific Hardware Accelerators.
To design and program Uni-core System on Chip (SoC) and Multi-core (SoC) architectures. Bus System Performance (data rate), Processor Performance (FLOPS), Memory Read Write Time.
To use an FPGA logic block for gate and switch level systems.
To develop a layout of semi custom ASIC logic cell of three input lookup table (LUT), an FPGA Configurable Logic Block (CLB by using VLSI Digital Schematic Editor & Simulator.
UCERD Gathering Intellectuals
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UCERD: Unal Center of Education Research and Development