Hardware description languages have been used for a long time and the primary hardware description languages in use are Verilog and VHDL. VHDL is a VHSIC Hardware Description Language and VHSIC is a very high speed integrated circuit gate level through system design and verification. Verilog is primarily targeted for design of application specific integrated circuits. Hardware description languages are used for hardware systems because of their parallelism. This parallelism results in increased speed
My passion for science and craze towards technology inspired me to take up engineering. I chose to major in Electronics and communication engineering with a great desire to contribute to this demanding field. During my under graduate study I learned the fundamentals of Electronics Engineering which together with practical course work strengthened my interest. Right from my school, I was focused towards Mathematics, Science and research in general. Due to the same reason, I took up Physics, chemistry
CHAPTER 3 INTRODUCTION OF DWT 3.1 3-D DWT Architecture The 3-D DWT can be considered as a combination of three one dimensional DWT in the x, y and z directions, as shown in Fig. 3.1. The preliminary work in the DWT processor design is to build 1-D DWT modules, which are composed of high-pass and low-pass filters that perform a convolution of filter coefficients and input pixels. After a one-level of - discrete wavelet transform, the volume of image is decomposed into HHH, HHL, HLH, HLL, LHH, LHL
research on circuits and systems design. Specifically, combinational logic and the unique approaches used by engineers in response to real-world problems, such as FSM, have left me fascinated. Therefore, successfully developing a taximeter using Verilog ranks among my most exhilarating experiences. I also gained considerable experience in programming when I developed a game called ‘Battle City’ with a GUI with two teammates. I took responsibility for the game’s animation and sound effects during
element and the use of the seven segment display on the Altera DE2-115 board. This experimentation with the clock and display are valuable since they are a precursor to future labs to come. In order to make these items work it required the use or Verilog code, which was given for parts 1, 2, and 3. In Part 1, the user was presented with code that enables use of the internal clock on the DE2-115(Appendix A-1). After compiling the user was to find a value for X would allow LEDR[0] on the DE2 to blink
“Dream, Dream and Dream. Dream transforms into thoughts. Thoughts results into action.” This famous quote by Dr. APJ Abdul Kalam is an inspiration for my life. After graduating my engineering from Visvesvaraya Technological University with flying colors, my next obvious dream was to pursue masters in my favorite subject VLSI. But I was of the opinion that I should gain some practical exposure by working in a research oriented organization to bridge the gap between theoretical knowledge and corporate
I am interested in Microelectronics and Applied Physics, particularly the solid-state electronic devices, and its fabrication and characterization techniques. While I always had a natural inclination towards physics and electronics because of my mother who is a physicist, I got really passionate in the field of nano-electronics during my undergraduate study at Indian Institute of Technology Gandhinagar (IIT-GN) and the research internship at University of Illinois at Chicago (UIC). During my Summer
Random access memory is an essential resource required by the computational hardware. As the processor speed has attained GHz clock frequency, memory throughput can be a bottleneck to achieve high performance. DRAM can deliver a reasonable solution for such data storage. Typical computational system consists of multiple hardware modules that perform different operations on the data. These modules attempt to access the data concurrently. This leads to a requisite for a memory controller that arbitrates