Phase constrained complex NMF: Separating overlapping partials in mixtures of harmonic musical sources

Bronson, James W.; Depalle, Philippe

doi:10.1109/icassp.2014.6855053

Cited by 15 publications

(28 citation statements)

References 12 publications

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“…The main difference between the PU algorithm and consistency-based approaches is that the former relies on a signal model while the latter exploit a property of the STFT. Such an approach has been used in the phase vocoder algorithm [23] for time stretching, and applied to speech enhancement [24], [25], audio restoration [26] and source separation [27]. In many cases, the mixtures are assumed to be in harmonic proportions, which means that the partial frequencies are integer multiples of a fundamental frequency, but the PU technique can be extended to signals which do not comply with this assumption [26].…”

Section: Introductionmentioning

confidence: 99%

Model-Based STFT Phase Recovery for Audio Source Separation

Magron

Badeau

David

2018

IEEE/ACM Trans. Audio Speech Lang. Process.

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For audio source separation applications, it is common to estimate the magnitude of the short-time Fourier transform (STFT) of each source. In order to further synthesizing time-domain signals, it is necessary to recover the phase of the corresponding complex-valued STFT. Most authors in this field choose a Wiener-like filtering approach which boils down to using the phase of the original mixture. In this paper, a different standpoint is adopted. Many music events are partially composed of slowly varying sinusoids and the STFT phase increment over time of those frequency components takes a specific form. This allows phase recovery by an unwrapping technique once a shortterm frequency estimate has been obtained. Herein, a novel iterative source separation procedure is proposed which builds upon these results. It consists in minimizing the mixing error by means of the auxiliary function method. This procedure is initialized by exploiting the unwrapping technique in order to generate estimates that benefit from a temporal continuity property. Experiments conducted on realistic music pieces show that, given accurate magnitude estimates, this procedure outperforms the state-of-the-art consistent Wiener filter.

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Section: Introductionmentioning

confidence: 99%

Model-Based STFT Phase Recovery for Audio Source Separation

Magron

Badeau

David

2018

IEEE/ACM Trans. Audio Speech Lang. Process.

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“…For instance, the widely used model of mixtures of sinusoids [9] can lead to explicit constraints for phase reconstruction that exploit the relationships between adjacent TF bins. This approach has been used in the phase vocoder algorithm [10], integrated into a CNMF framework [11] and applied to speech signal reconstruction [12]. In [13], we proposed to generalize this approach and have provided a phase unwrapping algorithm that has been applied to an audio signal restoration task.…”

Section: Introductionmentioning

confidence: 99%

Complex NMF under phase constraints based on signal modeling: Application to audio source separation

Magron

Badeau

David

2016

2016 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

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Nonnegative Matrix Factorization (NMF) is a powerful tool for decomposing mixtures of audio signals in the Time-Frequency (TF) domain. In the source separation framework, the phase recovery for each extracted component is necessary for synthesizing time-domain signals. The Complex NMF (CNMF) model aims to jointly estimate the spectrogram and the phase of the sources, but requires to constrain the phase in order to produce satisfactory sounding results. We propose to incorporate phase constraints based on signal models within the CNMF framework: a phase unwrapping constraint that enforces a form of temporal coherence, and a constraint based on the repetition of audio events, which models the phases of the sources within onset frames. We also provide an algorithm for estimating the model parameters. The experimental results highlight the interest of including such constraints in the CNMF framework for separating overlapping components in complex audio mixtures.

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“…Alternatively, one can extract phase constraints from the sinusoidal model, which is widely used for representing audio signals [11,22]. It can be shown [23] that the STFT phase µ of a signal modeled as a sum of sinusoids in the time domain follows the phase unwrapping (PU) equation:…”

Section: Sinusoidal Modelmentioning

confidence: 99%

“…It has been used in many audio applications, including time stretching [23], speech enhancement [22] and source separation [7,11,24].…”

Section: Sinusoidal Modelmentioning

confidence: 99%

“…Phase recovery algorithms exploit phase constraints that originate from consistency [8], a property of the STFT that arises from its redundant signal representation, or from a signal model that approximates time-domain signals as a sum of sinusoids [7]. The above mentioned phase constraints have been applied to a source separation task [9,7] and combined with magnitude estimation techniques in order to design full and phase-aware separation systems [10,11]. However, these systems are based on variants of NMF methods, which provides fairly good separation results in scenarios where the sources are well represented with stationary spectral atoms (over time) and uniform temporal activations (over frequencies).…”

Section: Introductionmentioning

confidence: 99%

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Reducing Interference with Phase Recovery in DNN-based Monaural Singing Voice Separation

et al. 2018

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State-of-the-art methods for monaural singing voice separation consist in estimating the magnitude spectrum of the voice in the short-time Fourier transform (STFT) domain by means of deep neural networks (DNNs). The resulting magnitude estimate is then combined with the mixture's phase to retrieve the complex-valued STFT of the voice, which is further synthesized into a time-domain signal. However, when the sources overlap in time and frequency, the STFT phase of the voice differs from the mixture's phase, which results in interference and artifacts in the estimated signals. In this paper, we investigate on recent phase recovery algorithms that tackle this issue and can further enhance the separation quality. These algorithms exploit phase constraints that originate from a sinusoidal model or from consistency, a property that is a direct consequence of the STFT redundancy. Experiments conducted on real music songs show that those algorithms are efficient for reducing interference in the estimated voice compared to the baseline approach.

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Phase constrained complex NMF: Separating overlapping partials in mixtures of harmonic musical sources

Cited by 15 publications

References 12 publications

Model-Based STFT Phase Recovery for Audio Source Separation

Model-Based STFT Phase Recovery for Audio Source Separation

Complex NMF under phase constraints based on signal modeling: Application to audio source separation

Reducing Interference with Phase Recovery in DNN-based Monaural Singing Voice Separation

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