Abstract
In this paper, combined with the partial differential equation music signal smoothing model, a new music signal recognition model is proposed. Experimental results show that this model has the advantages of the above two models at the same time, which can remove noise and enhance music signals. This paper also studies the music signal recognition method based on the nonlinear diffusion model. By distinguishing the flat area and the boundary area of the music signal, a new diffusion coefficient equation is obtained by combining these two methods, and the corresponding partial differential equation is discretized by the finite difference method with numerical solution. The application of partial differential equations in music signal processing is a relatively new topic. Because it can accurately model the music signal, it solves many complicated problems in music signal processing. Then, we use the group shift Fourier transform (GSFT) to transform this partial differential equation into a linear homogeneous differential equation system, and then use the series to obtain the solution of the linear homogeneous differential equation system, and finally use the group shift inverse Fourier transform to obtain the noise frequency modulation time-dependent solution of the probability density function of the interference signal. This paper attempts to use the mathematical method of stochastic differentiation to solve the key problem of the time-dependent solution of the probability density function of noise interference signals and to study the application of random differentiation theory in radar interference signal processing and music signal processing. At the end of the thesis, the application of stochastic differentiation in the filtering processing of music signals is tried. According to the inherent self-similarity of the music signal system and the completeness and stability of the empirical mode decomposition (EMD) algorithm, a new kind of EMD music using stochastic differentiation is proposed for signal filtering algorithm. This improved anisotropic diffusion method can maintain and enhance the boundary while smoothing the music signal. The filtering results of the actual music signal show that the algorithm is effective.
Highlights
Music signal restoration and enhancement is an important part of music signal processing, and it is a problem of early auditory music signal processing
The algorithms based on impact filters, partial differential equations, and anisotropic diffusion studied in this paper are important components of many music signal processing methods based on partial differential equations, and they have positive significance for the improvement of these models and numerical calculations
We improve the accuracy of the antidiffusion gradient estimation, greatly reduce the number of iterations of the overall algorithm, and reduce the model’s misjudgment of noise points and edge points so that the new algorithm outputs music signals in various areas that are properly smoothed while the edges are still compared sharp and clear
Summary
Music signal restoration and enhancement is an important part of music signal processing, and it is a problem of early auditory music signal processing. The use of traditional linear filters to restore and enhance the music signal contaminated by noise will blur or even destroy the discontinuous information of the music signal boundary, while the anisotropic diffusion filter based on partial differential equations can denoise and at the same time well keep the music signal [7]. We focus on the simple and practical wavelet threshold denoising method, and aiming at the shortcomings of its threshold denoising, we propose a denoising method based on wavelet transform and Wiener filtering and introduce the modeling and denoising method of partial differential equation image processing. The research topic of this article has a certain theoretical background and strong practical value
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