Abstract
Estimating the direction-of-arrival (DOA) of multiple acoustic sources is one of the key technologies for humanoid robots and drones. However, it is a most challenging problem due to a number of factors, including the platform size which puts a constraint on the array aperture. To overcome this problem, a high-resolution DOA estimation algorithm based on sparse Bayesian learning is proposed in this paper. A group sparse prior based hierarchical Bayesian model is introduced to encourage spatial sparsity of acoustic sources. To obtain approximate posteriors of the hidden variables, a variational Bayesian approach is proposed. Moreover, to reduce the computational complexity, the space alternating approach is applied to push the variational Bayesian inference to the scalar level. Furthermore, an acoustic DOA estimator is proposed to jointly utilize the estimated source signals from all frequency bins. Compared to state-of-the-art approaches, the high-resolution performance of the proposed approach is demonstrated in experiments with both synthetic and real data. The experiments show that the proposed approach achieves lower root mean square error (RMSE), false alert (FA), and miss-detection (MD) than other methods. Therefore, the proposed approach can be applied to some applications such as humanoid robots and drones to improve the resolution performance for acoustic DOA estimation especially when the size of the array aperture is constrained by the platform, preventing the use of traditional methods to resolve multiple sources.
Highlights
Acoustic direction-of-arrival (DOA) estimation is a key technology in audio signal processing where it enables source localization for humanoid robots [1, 2], drones [3, 4], teleconferencing [5, 6], and hearing aids [7]
1.2 the modeling parameters a, b, c, and d are all set to 1e − 3, the parameter η is set to 0.1, the threshold for the space alternating variational estimation (SAVE)-multi-snapshot SBL (MSBL) algorithm errmax is set to 1e − 10, and the threshold for the expectation– maximization (EM) algorithm err0 is set to 1e − 3
4.2.1 Recovery performance analysis using a uniform linear array (ULA) we test the recovery performance of the proposed SAVE-MSBL algorithm using four acoustic sources comprising pure sinusoidal signals
Summary
Acoustic direction-of-arrival (DOA) estimation is a key technology in audio signal processing where it enables source localization for humanoid robots [1, 2], drones [3, 4], teleconferencing [5, 6], and hearing aids [7]. Sparse signal recovery-based DOA estimation methods have enjoyed much success in recent decades by exploiting the sparsity of sources in the spatial domain [18, 19]. To reduce the computational complexity of the wide-band approach, a computationally efficient DOA estimation method was proposed in [33] based on a sparse Bayesian framework. In [35], we proposed an SBL-based acoustic reflector localization method, which models the acoustic reflector localization problem as a sparse signal recovery problem. The rest of this paper is organized as follows: In Section 2, we pose the narrow-band acoustic DOA estimation problem as a sparse signal recovery problem with an over-complete dictionary.
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