Welcome to Advanced Topics in Acoustic Array Signal Processing
Description:
Acoustic arrays are becoming a ubiquitous technology in many places, including in consumer electronics and healthcare technology. Microphone arrays are now found in smartphones, laptops, TVs, etc., and loudspeaker arrays are emerging as a promising technology in home entertainment systems, car audio systems, public announcement systems. Moreover, as wireless communication capabilities are becoming widespread, audio devices can now form ad hoc networks and cooperate when solving signal processing problems, such as estimation and filtering. This offers many new possibilities but also poses many new challenges, as it requires that many difficult, technical problems must be solved. In the course, a general introduction to acoustic array signal processing will be given, including commonly used models and assumptions as well as classical methods for solving problems such as localization, beamforming and noise reduction. The remainder of the course is then devoted to recent advances in acoustic array signal processing and applications. These include advances within, for example, model-based localization and beamforming, sound zone control with loudspeaker arrays, multi-channel noise reduction in ad hoc microphone arrays, noise statistics estimation, speech intelligibility prediction, and speech enhancement in binaural hearing aids.
The course is dedicated to the following subjects:
- Fundamentals: Definitions, narrow-band signals, near-filed and far-field, array manifold vector. Beamforming, uniform linear array, directivity pattern. Performance criteria (beam-width, sidelobe level, directivity, white noise gain). Sensitivity. Sampling of continuous aperture. Wide-band signals and nested arrays.
- Space-time random processes: Snapshots, spatial correlation matrix, signal and noise subspaces.
- Optimal array processors: MVDR (Capon), MPDR, Maximum SNR, MMSE, LCMV.
- Sensitivity and robustness: Noise fields and multi-path and their influence on performance. Superdirective beamformer. Diagonal loading.
- Adaptive spatial filtering: Frost method, generalized sidelobe canceller (GSC).
- Parameter estimation (DoA): ML estimation, resolution, Cramér-Rao lower bound.
- Classical methods for localization: Classical methods (Bartlett), method based on eigen-decomposition: Pisarenko, MUSIC, ESPRIT. Resolution. MVDR estimation. Performance evaluation and comparison.
- Advances: Model-based processing and estimation, multi-channel noise reduction, ad hoc microphone arrays.
- Applications: Speech processing, hearing aids, wireless acoustic sensor networks, loudspeaker arrays.
Prerequisites:
A basic knowledge of mathematics as obtained through undergraduate engineering studies.
Organizer: Prof. Mads Græsbøll Christensen
Lecturers: Sharon Gannot, Assistant Prof. Jesper Rindom Jensen, Assistant Prof. Jesper Kjær Nielsen, Prof. Mads Græsbøll Christensen
ECTS: 4
Time: August 13-17 2018
Place:
City:
Number of seats: 25
Deadline: July 23 2018
Important information concerning PhD courses We have over some time experienced problems with no-show for both project and general courses. It has now reached a point where we are forced to take action. Therefore, the Doctoral School has decided to introduce a no-show fee of DKK 5,000 for each course where the student does not show up. Cancellations are accepted no later than 2 weeks before start of the course. Registered illness is of course an acceptable reason for not showing up on those days. Furthermore, all courses open for registration approximately three months before start. This can hopefully also provide new students a chance to register for courses during the year. We look forward to your registrations
- Teacher: Mads Græsbøll Christensen
- Teacher: Jesper Rindom Jensen