Ancient Vedic Multiplication Based Optimized High Speed Arithmetic Logic

Here, we deal with most effective Vedic multiplication method dependent 4*4 bit arithmetic logic unit having high speed. In this paper, we will perform ALU operations. ALU is a development of research work that has been done for years so we have chosen this topic. Normally ALU is a heart of digital processor, central processing unit, microprocessor and micro controller. Every digital domain based technology has to depend on the performance of ALU. Hence, there is a necessity of ALU which generates high speeds which depends on the speed of multiplier. Therefore, we go for designing a 4-bit multiplier. To generate high speeds, multiplier is employed which is one of the important blocks of the hardware unit and also an important initiation of delay in the path. We have studied many algorithms for multiplication technique but research says that Vedic multiplication is most effective of all in terms of speed. The algorithm contains 16 sutra, out of which we are employing URDHVA TIRYAKBHYAM and the code is written in Very High Speed Integrated Circuit Hardware Description. Our supporting synthesizing and simulating tools are Xilinx ISE9.2i and model sim-altra6.3g-pi (Quartus II) respectively. At last, we will compare 4-bit ALU with 4-bit Array ALU.    &nbsp

Video signal processing system uses gated current mode switches to perform high speed multiplication and digital-to-analog conversion

Video signal processor uses special-purpose integrated circuits with nonsaturating current mode switching to accept texture and color information from a digital computer in a visual spaceflight simulator and to combine these, for display on color CRT with analog information concerning fading

A Technical Review of Efficient and High Speed Adders for Vedic Multipliers

In the VLSI system design, the main regions of research are the reduced size & increase speed path logic systems. A fundamental requirement of high speed, addition and multiplication is always needed for the high performance digital processors. In the digital system, the speed of addition depend on the propagation of carry, which is generated successively, after the previous bit has been summed & carry is propagated, into the next location. There are numerous types of adders available likes Ripple Carry Adder, Carry Look Ahead Adder, Carry Save Adder, Carry Avoid Adder, and Carry Select Adder, which have their own benefits and drawbacks. With the advances technology, proposal of Carry select adder (CSA) which deals either of the high speed, low power consumption, regularity of layout a smaller amount area and compact VLSI design implementation. Researchers justify that Ripple Carry Adder had a lesser area but having lesser in speed, in comparing with Carry Select Adders are fastest speed but possess a larger area. The Carry Look Ahead Adder is in between the spectrum having proper trade-offs between time and area complexities

VHDL Implementation of Fastest Braun’s Multiplier

Multiplication is an essential arithmetic operation for common Digital Signal Processing (DSP) applications, such as filtering and Fast Fourier Transform (FFT). To achieve high execution speed, parallel array multipliers are widely used. To decrease computational delay and improve resource utilization carry look-ahead adder circuit are use and Braun’s-architectures multiplier is compared with its conventional architectural. DOI: 10.17762/ijritcc2321-8169.15057

Performance evaluation of high speed compressors for high speed multipliers

This paper describes high speed compressors for high speed parallel multipliers like Booth Multiplier, Wallace Tree Multiplier in Digital Signal Processing (DSP). This paper presents 4-3, 5-3, 6-3 and 7-3 compressors for high speed multiplication. These compressors reduce vertical critical path more rapidly than conventional compressors. A 5-3 conventional compressor can take four steps to reduce bits from 5 to 3, but the proposed 5-3 takes only 2 steps. These compressors are simulated with H-Spice at a temperature of 25°C at a supply voltage 2.0V using 90nm MOSIS technology. The Power, Delay, Power Delay Product (PDP) and Energy Delay Product (EDP) of the compressors are calculated to analyze the total propagation delay and energy consumption. All the compressors are designed with half adder and full Adders only