Thursday, 27 January 2022

Low Power Low Voltage Bulk Driven Balanced OTA

Neha Gupta, Sapna Singh, Meenakshi Suthar and Priyanka Soni

Faculty of Engineering Technology, Mody Institute of Technology and Science, Lakshmangarh, Sikar, India

ABSTRACT

The last few decades, a great deal of attention has been paid to low-voltage (LV) low-power (LP) integrated circuits design since the power consumption has become a critical issue. Among many techniques used for the design of LV LP analog circuits, the Bulk-driven principle offers a promising route towards this design for many aspects mainly the simplicity and using the conventional MOS technology to implement these designs. This paper is devoted to the Bulk-driven (BD) principle and utilizing this principle to design LV LP building block of Operational Transconductance Amplifier (OTA) in standard CMOS processes and supply voltage 0.9V. The simulation results have been carried out by the Spice simulator using the 130nm CMOS technology from TSMC.

KEYWORDS

Bulk-driven MOS, OTA, BOTA, Body effect

Original Source URL: https://aircconline.com/vlsics/V2N4/2411vlsics11.pdf

https://airccse.org/journal/vlsi/vol2.html







Thursday, 20 January 2022

Design and ASIC Implemenatation of DUC/DDC for Communication Systems

Naagesh S. Bhat

Senior Product Engineer, Green Mil International Ltd., Bangalore, India

ABSTRACT

Communication systems use the concept of transmitting information using the electrical distribution network as a communication channel. To enable the transmission data signal modulated on a carrier signal is superimposed on the electrical wires. Typical power lines are designed to handle 50/60 Hz of AC power signal; however they can carry the signals up to 500 KHz frequency. This work aims to aid transmission/reception of an audio signal in the spectrum from 300 Hz to 4000 Hz using PLCC on a tunable carrier frequency in the spectrum from 200 KHz to 500 KHz. For digital amplitude modulation the sampling rate of the carrier and the audio signal has to be matched. Tunable carrier generation can be achieved with Direct Digital Synthesizers at a desired sampling rate. DSP Sample rate conversion techniques are very useful to make the sampling circuits to work on their own sampling rates which are fine for the data/modulated-carrier signal’s bandwidth. This also simplifies the complexity of the sampling circuits. Digital Up Conversion (DUC) and Digital Down Conversion (DDC) are DSP sample rate conversion techniques which refer to increasing and decreasing the sampling rate of a signal respectively. 

The objective was to design and implement low power ASIC of DUC and DDC designs at 65nm for PLCC. Low power implementation was carried out using Multi-VDD technique. MATLAB software models were used to understand the DUC and DDC designs. RTL to GDS flow was executed using Synopsys tools such as VCS, Design Compiler, IC Compiler and PrimeTime. Key milestones of this activity are RTL verification, synthesis, gate-level simulations, low power architecture definitions, physical implementation, ASIC signoff checks and postroute delay based simulations. Multi-VDD technique deployed on DUC and DDC helped to reduce the power consumption from 280.9uW to 198.07uW and from 176.26uW to 124.47uW respectively. DUC and DUC designs have met functionality at 64MHz clock frequency. Both the designs have passed postroute delay based simulations, static performance checks, power domain checks and TSMC’s 65nm design rule checks.

KEYWORDS

Power Line Carrier Communication, Digital Down-Counter, Digital Up-Counter, Application Specific Integrated Circuit, Multi-VDD, TSMC 

Original Source URL: https://aircconline.com/vlsics/V2N4/2411vlsics10.pdf

https://airccse.org/journal/vlsi/vol2.html







Thursday, 13 January 2022

An Efficient FPGA Implemenation of MRI Image Filtering and Tumour Characterization Using XILINX System Generator

S. Allin Christe, M. Vignesh and A. Kandaswamy, PSG College of Technology, India

ABSTRACT

This paper presents an efficient architecture for various image filtering algorithms and tumor characterization using Xilinx System Generator (XSG). This architecture offers an alternative through a graphical user interface that combines MATLAB, Simulink and XSG and explores important aspects concerned to hardware implementation. Performance of this architecture implemented in SPARTAN-3E Starter kit (XC3S500E-FG320) exceeds those of similar or greater resources architectures. The proposed architecture reduces the resources available on target device by 50%.

KEYWORDS

MRI, Matlab, Xilinx System Generator, FPGA, Edge Detection

Original Source URL: https://aircconline.com/vlsics/V2N4/2411vlsics09.pdf

https://airccse.org/journal/vlsi/vol2.html




Thursday, 6 January 2022