DSP architecture with folded tree for power constraint devices

2014 Sixth International Conference on Advanced Computing (ICoAC) Pub Date : 2014-12-01 DOI:10.1109/ICOAC.2014.7229757

K. Ranjithkumar, T. Anandharajan

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引用次数: 1

Abstract

Energy consumption in Digital Signal Processing (DSP) application is a vital parameter of consideration. Mostly DSP applications deplete power. Battery constraint is important in many mobiles, processors, and sensor-related devices. The major critical operations in DSP architecture are multiplication and addition. Multiplication process is performed using repetitive addition. Hence, adder is the basic component used in digital signal processor. DSP architecture is proposed with the energy-efficient goal. Traditional carry select adder contains ripple carry adder block is replaced by parallel prefix adder. By replacing that block and introducing folded tree, we can reduce power used by DSP processors. This architecture can be used in all power constrained DSP applications. In the existing system, folded tree is used in architecture to reduce the number of processing elements, and they used carry look-ahead adder to perform the internal processing element operations. In the proposed system, carry look-ahead adder is replaced by LFA and PA to harness the energy depleted in an application (e.g., DSP application). Power consumption is reduced by 12-15% as compared with the existing algorithms using Cyclone III (EP3C16F484C6).

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功率约束器件的折叠树DSP结构

在数字信号处理(DSP)应用中，能量消耗是一个重要的考虑参数。大多数DSP应用会消耗功率。电池限制在许多移动设备、处理器和传感器相关设备中都很重要。在DSP体系结构中，最关键的运算是乘法和加法。乘法运算是用重复加法来完成的。因此，加法器是数字信号处理器的基本元件。提出了以节能为目标的DSP架构。传统进位选择加法器包含纹波进位加法器块被并行前缀加法器取代。通过替换该块并引入折叠树，可以降低DSP处理器的功耗。该架构可用于所有功率受限的DSP应用。现有系统在架构上采用折叠树来减少处理元素的数量，并采用进位预判加法器来完成内部处理元素的操作。在所提出的系统中，进位前视加法器被LFA和PA取代，以利用在应用(例如DSP应用)中耗尽的能量。与使用Cyclone III (EP3C16F484C6)的现有算法相比，功耗降低了12-15%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2014 Sixth International Conference on Advanced Computing (ICoAC)

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