基于改进无延迟频域算法的汽车风噪主动控制研究

doi:10.19562/j.chinasae.qcgc.2025.08.016

Abstract

Abstract:

Wind noise is one of the main sources of interior noise in high-speed driving of new energy vehicles. Wind noise control by traditional structural design has problems such as difficulty in control and unclear noise reduction effect. In this article， an improved delayless frequency domain filtering active noise control algorithm based on secondary path equalization and frequency domain segmented variable step size method. This algorithm has the characteristics of lower computational complexity and less frequency dependence on system noise reduction performance compared to traditional filtering minimum mean square （FxLMS） algorithms， and can achieve good noise reduction effect over a wide frequency range. A dual channel simulation model of the algorithm is built in SIMULINK to simulate the noise reduction control effect of broadband wind noise， and a wind noise active control test bench is set up in a semi anechoic chamber for testing and verification. The results show that based on the wind noise data measured in real vehicles under high-speed conditions， the improved delayless frequency domain filtering algorithm proposed in this paper has significantly better noise reduction effect than the traditional FxLMS algorithm， with the noise reduction of about 9.42 dB（A） and 8.81 dB（A） at two target positions. This research result can provide new ideas and methods for active control and application of automotive wind noise.

Key words: automobile wind noise, active control of wind noise, delayless frequency domain algorithm, secondary path equalization, variable step size in frequency segmentation

Huijun Ji,Chihua Lu,Wan Chen,Zhien Liu,Ying Wang,Yongliang Wang,Menglei Sun. Research on Active Control of Automotive Wind Noise Based on Improved Delayless Frequency Domain Algorithm[J].Automotive Engineering, 2025, 47(8): 1607-1615.

Figures/Tables 17

References 14

[1]	沈远航.汽车侧窗区域气动噪声特性仿真与控制研究［D］. 长春：吉林大学， 2020. DOI：10.27162/d. cnki.gjlin. 2020.005496.
	SHEN Y H. Research on simulation and control of aerodynamic noise characteristics in automobile side window area［D］. Changchun： Jilin University，2020. DOI：10.27162/d. cnki.gjlin. 2020.005496.
[2]	SAMARASINGHE P N， ZHANG W， ABHAYAPALA T D. Recent advances in active noise control inside automobile cabins： toward quieter cars［J］. IEEE Signal Processing Magazine， 2016，33（6）： 61-73.
[3]	古志武，石黎，陈锴，等. 高速行驶汽车的座舱噪声有源控制实验研究［J］.南京大学学报（自然科学版）， 2024，60（5）： 848-859.
	GU Z W，SHI L，CHEN K，et al. An experimental study on active noise control in the cabin of high-speed vehicles［J］. Journal of Nanjing University（Natural Science Edition）， 2024，60（5）： 848-859.
[4]	庞剑.汽车路噪控制理论与应用［M］.北京：机械工业出版社， 2024.
	PANG J. Control of automotive road noise theory and application［M］. Beijing：China Machine Press， 2024.
[5]	CHANG D C，CHU F T. Feedforward active noise control with a new variable tap-length and step-size filtered-X LMS algorithm［J］. Audio， Speech， and Language Processing， IEEE/ACM Transactions on， 2014， 22（2）： 542-555.
[6]	周政道.纯电动汽车路噪主动控制方法及其性能优化研究［D］.长春：吉林大学，2023. DOI：10.27162/d.cnki. gjlin. 2023. 006956.
	ZHOU Z D. Research on active road noise control method and its performance optimization in pure electric vehicles［D］. Changchun： Jilin University，2023. DOI：10.27162/d.cnki. gjlin.2023. 006956.
[7]	周雪莲，贺岩松，苏宏健，等.基于可变阶陷波算法的混合动力汽车阶次噪声主动控制［J］.中国机械工程，2024，35（11）： 2082-2089.
	ZHOU X L，HE Y S，SU H J， et al. Active control of order noise in hybrid electric vehicles based on variable-order notch algorithm［J］. China Mechanical Engineering，2024，35（11）： 2082-2089.
[8]	袁军，刘东旭，吕韦喜，等. 基于汽车风噪的主动噪声控制系统的研究与设计［J］. 重庆理工大学学报（自然科学）， 2019，33（10）：9-15.
	YUAN J，LIU D X，LV W X，et al. Design of active noise control system based on vehicle wind noise［J］. Journal of Chongqing University of Technology （Natural Sciences）， 2019，33（10）：9-15.
[9]	方鼎.主被动降噪方法在汽车风振噪声控制中的应用研究［D］. 长沙：湖南大学，2021.DOI：10.27135/d.cnki.ghudu. 2021. 001246.
	FANG D. Research on the application of active and passive noise reduction methods in vehicle wind buffeting noise control［D］. Changsha： Hunan University， 2021.DOI：10. 27135/d. cnki.ghudu.2021. 001246.
[10]	吴开明.基于频域自适应算法的车内主动噪声控制方法研究［D］.长春：吉林大学， 2021.DOI：10.27162/d.cnki.gjlin. 2021. 005690.
	WU K M. Research on active noise control method in vehicle based on frequency domain adaptive algorithm［D］. Changchun： Jilin University， 2021. DOI：10. 27162/d. cnki.gjlin. 2021. 005690.
[11]	CLARK G， MITRA S， PARKER S. Block implementation of adaptive digital filters［J］. Acoustics， Speech and Signal Processing， IEEE Transactions on， 1981，29（3）： 744-752.
[12]	ELLIOT S. Signal processing for active control［M］. Elsevier： Ebsco Publishing ［Distributor］， 2001.
[13]	CHEN W， XIE L P， GUO J J， et al.A computationally efficient feedforward time-frequency-domain hybrid active sound profiling algorithm for vehicle interior noise［J］. Mechanical Systems and Signal Processing， 2023，194： 110279.
[14]	彭媛.基于频域自适应算法的吸油烟机主动降噪［D］. 长春：吉林大学， 2023.DOI：10.27162/d. cnki.gjlin.2023.001270.
	PENG Y. Active noise reduction of range hood based on frequency domain adaptive algorithm［D］. Changchun： Jilin University， 2023.DOI：10. 27162/d.cnki.gjlin. 2023.001270.

速度工况	位置	算法	降噪量
100 km/h	主驾左耳	传统FxLMS	2.44
		无延迟频域滤波算法	6.27
		改进无延迟频域滤波算法	10.31
	副驾右耳	传统FxLMS	3.30
		无延迟频域滤波算法	6.40
		改进无延迟频域滤波算法	8.85
120 km/h	主驾左耳	传统FxLMS	5.89
		无延迟频域滤波算法	8.39
		改进无延迟频域滤波算法	9.92
	副驾右耳	传统FxLMS	4.00
		无延迟频域滤波算法	8.19
		改进无延迟频域滤波算法	10.63

速度工况	位置	算法	降噪量
100 km/h	主驾左耳	传统FxLMS	2.97
		无延迟频域滤波算法	7.24
		改进无延迟频域滤波算法	8.15
	副驾右耳	传统FxLMS	5.76
		无延迟频域滤波算法	6.42
		改进无延迟频域滤波算法	8.92
120 km/h	主驾左耳	传统FxLMS	6.25
		无延迟频域滤波算法	8.37
		改进无延迟频域滤波算法	9.42
	副驾右耳	传统FxLMS	4.17
		无延迟频域滤波算法	6.11
		改进无延迟频域滤波算法	8.81

Research on Active Control of Automotive Wind Noise Based on Improved Delayless Frequency Domain Algorithm

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References 14

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