一种新的最速下降算法在自适应噪声对消中的应用

王帅; 向建军; 彭芳; 肖冰松

doi:10.13700/j.bh.1001-5965.2020.0218

一种新的最速下降算法在自适应噪声对消中的应用

doi: 10.13700/j.bh.1001-5965.2020.0218

空军工程大学航空工程学院, 西安 710038

基金项目:

航空科学基金 20175596020

详细信息

通讯作者:
向建军, E-mail: xiang_jj@sohu.com

中图分类号: TN911.7
计量
- 文章访问数: 472
- HTML全文浏览量: 70
- PDF下载量: 40
- 被引次数: 0
出版历程
- 收稿日期: 2020-05-27
- 录用日期: 2020-09-04
- 网络出版日期: 2021-07-20

Application of a new steepest descent algorithm in adaptive noise cancellation

College of Aeronautical Engineering, Air Force Engineering University, Xi'an 710038, China

Funds:

Aeronautical Science Foundation of China 20175596020

More Information

Corresponding author: XIANG Jianjun, E-mail: xiang_jj@sohu.com

摘要

摘要:
自适应噪声对消在很多领域有着重要应用。为了进行自适应噪声对消，提出了一种新的最速下降算法。该算法主要原理是对多元二次函数进行降维处理，使其变成一元二次函数，再应用抛物线的性质分别循环迭代地求解每一个维度上的极值。在自适应噪声对消应用中，所提算法与传统的自适应算法进行对比，具有收敛速度快，滤波效果好，滤波效果可调节，抗恶劣信噪比以及急剧变化信噪比，不需选择迭代步长，适合计算机和可编程硬件实现等优点。
- 自适应算法 /
- 最速下降算法 /
- 噪声对消 /
- 最小均方误差 /
- 自适应滤波器
Abstract:
Adaptive noise cancellation has important applications in many fields. In order to carry out adaptive noise cancellation, a new steepest descent algorithm is proposed. The main principle of the algorithm is to reduce the dimension of multivariate quadratic function to make it become a univariate quadratic function, and then apply the properties of parabola to iteratively solve the extremum of each dimension. Compared with the traditional adaptive algorithm, the new steepest descent algorithm shows the advantages of fast convergence, good filtering effect, adjustable filtering effect, resisting bad SNR and sharp change SNR, no need to choose iteration step, and suitable for computer and programmable hardware implementation.
- adaptive algorithm /
- steepest descent algorithm /
- noise cancellation /
- minimum mean square error /
- adaptive filter

HTML全文

图 1 自适应滤波器示意图

Figure 1. Schematic diagram of adaptive filter

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图 2 时域波形图

Figure 2. Time domain waveform

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图 3 4种算法收敛速度对比

Figure 3. Comparison of convergence rates amongfour algorithms

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图 4 4种算法滤波效果对比

Figure 4. Comparison of filtering results among four algorithms

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图 5 实际信号处理的时域波形图

Figure 5. Time domain waveform of actual signal processing

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图 6 实际信号处理的频域波形图

Figure 6. Frequency domain waveform of actual signal processing

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图 7 约束方程个数对滤波效果的影响

Figure 7. Influence of the number of constraint equations on filtering result

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图 8 信噪比对滤波效果影响

Figure 8. Influence of SNR on filtering result

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