A Low Complexity DDS Based On Optimized CORDIC Algorithm

2019 IEEE 13th International Conference on ASIC (ASICON) Pub Date : 2019-10-01 DOI:10.1109/ASICON47005.2019.8983676

Shang Ma, Xuesi Wang, Yongjie Li, Kai Long, Bixin Zhu, Xin Lei

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引用次数: 3

Abstract

Aiming at the high-speed and low complexity of Direct Digital Frequency Synthesizer (DDS), this paper presents an improved structure of CORDIC algorithm (the excess-four algorithm). The mathematical approximate calculation is used to optimize the circuit structure of the rotating module in the excess-four algorithm, which reduces the adder in the rotating module and the hardware consumption of the circuit effectively. By removing the carry-over operation of the phase accumulating module, all the three-level rotating modules have the same structure, which ensures the same delay in all rotating units. The approach makes more advantages in the design of high-speed DDS circuits. Using the improved rotating structure, this paper implements the design of a highspeed DDS digital unit up to 6Gsps, with the SFDR above 88dBc, up to 104dBc. The single DDS core area is approximately 0.14 mm2 and the power consumption is 0.01mW/ MHz, using the Synopsys' SMIC 65nm process library tool to complete ASIC back-end design. In the case of SFDR that meets most of the high-speed DDS digital parts, the area and power consumption in this paper are greatly improved, compared with the conventional implementation method.

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基于优化CORDIC算法的低复杂度DDS

针对直接数字频率合成器(Direct Digital Frequency Synthesizer, DDS)高速、低复杂度的特点，提出了一种改进的CORDIC算法结构。在过四算法中，采用数学近似计算对旋转模块的电路结构进行优化，有效地减少了旋转模块中的加法器，降低了电路的硬件消耗。通过去掉积相模块的结转操作，所有的三级旋转模块都具有相同的结构，保证了所有旋转单元的延迟相同。该方法在高速DDS电路的设计中更有优势。本文采用改进的旋转结构，实现了高达6Gsps的高速DDS数字单元的设计，SFDR在88dBc以上，最高可达104dBc。单DDS核心面积约为0.14 mm2，功耗为0.01mW/ MHz，采用Synopsys的中芯国际65nm制程库工具完成ASIC后端设计。在满足大多数高速DDS数字器件的SFDR情况下，与传统实现方法相比，本文的面积和功耗大大提高。

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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2019 IEEE 13th International Conference on ASIC (ASICON)

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