Spectrogram Image Analysis of Error Signals for Minimizing Impulse Noise

This paper presents the theoretical and experimental study on the spectrogram image analysis of error signals for minimizing the impulse input noises in the active suppression of noise. Impulse inputs of some specific wave patterns as primary noises to a one-dimensional duct with the length of 1800 mm are shown. The convergence speed of the adaptive feedforward algorithm based on the least mean square approach was controlled by a normalized step size which was incorporated into the algorithm. The variations of the step size govern the stability as well as the convergence speed. Because of this reason, a normalized step size is introduced as a new method for the control of impulse noise. The spectrogram images which indicate the degree of the attenuation of the impulse input noises are considered to represent the attenuation with the new method. The algorithm is extensively investigated in both simulation and real-time control experiment. It is demonstrated that the suggested algorithm worked with a nice stability and performance against impulse noises. The results in this study can be used for practical active noise control systems.

[1]  Kunal Kumar Das,et al.  Frequency-Domain Block Filtered-x NLMS Algorithm for Multichannel ANC , 2008, 2008 First International Conference on Emerging Trends in Engineering and Technology.

[2]  Marco Anisetti,et al.  Fuzzy Weighted Approach to Improve Visual Quality of Edge-Based Filtering , 2007, IEEE Transactions on Consumer Electronics.

[3]  Young-Sup Lee,et al.  Simple feed-forward active control method for suppressing the shock response of a flexible cantilever beam , 2009 .

[4]  P. Gardonio,et al.  Coupling analysis of a matched piezoelectric sensor and actuator pair for vibration control of a smart beam. , 2002, The Journal of the Acoustical Society of America.

[5]  Gwanggil Jeon,et al.  Weight Assignment Method for Interpolation , 2012 .

[6]  Gwanggil Jeon,et al.  Noise Level Estimation for Image Processing , 2012, ICHIT.

[7]  Yoshinobu Kajikawa,et al.  Feedback active noise control system combining linear prediction filter , 2010, 2010 18th European Signal Processing Conference.

[8]  Issa M. S. Panahi,et al.  Hybrid FxRLS-FxNLMS Adaptive Algorithm for Active Noise Control in fMRI Application , 2011, IEEE Transactions on Control Systems Technology.

[9]  D. Bismor LMS Algorithm Step Size Adjustment for Fast Convergence , 2012 .

[10]  Gwanggil Jeon,et al.  A Filter-Based Format Conversion Approach , 2012, ICHIT.

[11]  Sivadasan Kottayi,et al.  ANC System for Noisy Speech , 2012 .

[12]  Stephen J. Elliott,et al.  Analysis and measurement of a matched volume velocity sensor and uniform force actuator for active structural acoustic control , 2001 .

[13]  Stephen J. Elliott,et al.  ACTIVE POSITION CONTROL OF A FLEXIBLE SMART BEAM USING INTERNAL MODEL CONTROL , 2001 .