This toolbox is a MATLAB implementation of the SUpDEq method, as presented in [1-7]. In general, the SUpDEq method is an approach to generate dense HRTF datasets based on sparsely measured HRTF datasets. For example, applying the SUpDEq method, a (technically) appropriate full-spherical dense HRTF dataset with 2702 directions can be derived from only 38 actually measured HRTFs.
Basically, the method attempts to remove direction-dependent temporal and spectral components of the sparse HRTF dataset by a spectral division (equalization) of the HRTFs with corresponding rigid sphere transfer functions (STFs). This equalized HRTF dataset is then transformed to the spherical harmonics (SH) domain by means of a spherical Fourier transform [9-10]. Next, a de-equalization is performed by extracting the equalized HRTFs at the spatial sampling points of the dense grid (SH-interpolation / spatial upsampling) and multiplying these HRTFs with the respective STFs in frequency domain.
A comparison of various methods for spherical harmonics interpolation of time-aligned (in terms of SUpDEq "equalized") HRTFs is presented in [7]. The study also contains a perceptual evaluation of the SUpDEq method.
The function supdeq_interpHRTF
furthermore contains various pre-processing and interpolation methods discussed in [7,8,11,18], which (in most cases) can be freely combined. The function also contains the post-interpolation magnitude correction MCA
(Magnitude-Corrected and Time-Aligned Interpolation) presented in [11] to further improve interpolation results obtained with time-aligned interpolation.
Various extensions of the toolbox, as presented in [2-8,20], allow e.g., the synthesis of near-field HRTFs based on far-field datasets (distance variation), distance error compensation of measured HRTF datasets, or low frequency extension of (equalized) measured HRTFs.
The toolbox is implemented in MATLAB R2015b, R2018a, R2020a, and R2022b and requires the Signal Processing Toolbox. Older versions of MATLAB might also work. The following third party toolboxes are required for full functionality. All listed toolboxes are part of the SUpDEq toolbox and are stored in the folder "thirdParty".
- SOFiA (Sound Field Analysis Toolbox) [12]
- AKtools [13]
- SOFA API (Spatially Oriented Format for Acoustics) [14]
- AMT (Auditory Modeling Toolbox) [15]
- SFS (Sound Field Synthesis Toolbox) [16]
- Triangle/Ray Intersection [17]
- SARITA (Spherical Array Interpolation by Time Alignment) [18]
SOFiA and AMT partly work with MEX files. The required MEX files for Mac and Windows (64 Bit) are pre-compiled and stored in the respective folders.
Simply clone or zip download this repository and add it to your Matlab path.
After installation, we recommend to go through the supdeq_demo
script step by step for the original SUpDEq implementation as presented in [1]. This will lead you through the basic processing. The resulting dense HRTF dataset can then be perceptually and technically compared to the (dense) reference HRTF dataset with the provided evaluation functions.
For an extended selection of pre-processing, interpolation, and post-processing methods, we recommend checking the supdeq_interpHRTF
function. The function provides various SUpDEq pre-processing methods as well as other time-alignment methods as described in [7]. The function allows SH, Natural Neighbor, Barycentric, or SARITA interpolation of the (pre-processed) HRTFs [7,8,18]. Pre-processing and interpolation can (in most cases) be freely combined to obtain the best results depending on the specific conditions. Moreover, the function allows to perform post-interpolation magnitude-correction using the MCA method (MCA - Magnitude-Corrected and Time-Aligned Interpolation) presented in [11], further improving the interpolation results. The script supdeq_demo_MCA
offers an easy introduction to MCA interpolation.
For our studies on near-field HRTFs and nearby sound sources (e.g., [19][20]), we implemented various methods for near-field HRTF synthesis based on far-field data, which we integrated in the SUpDEq toolbox. The function supdeq_dvf
allows synthesizing near-field HRTFs using distance variation functions (DVFs) in combination with acoustic parallax effects, as used for the listening experiments in [20]. With the function supdeq_rangeExt
, HRTFs in SH domain can be shifted in distance using radial functions.
A HTML documentation of the MATLAB code can be found here:
http://audiogroup.web.th-koeln.de/SUpDEq_doc/index.html
The third-party toolboxes are excluded from the documentation.
Johannes M. Arend and Christoph Pörschmann
TH Köln - University of Applied Sciences
Institute of Communications Engineering
Department of Acoustics and Audio Signal Processing
Betzdorfer Str. 2, D-50679 Cologne, Germany
https://www.th-koeln.de/akustik
J. M. Arend is now at Technical University of Berlin
Audio Communication Group
Einsteinufer 17c, D-10587 Berlin, Germany
https://www.ak.tu-berlin.de/menue/fachgebiet_audiokommunikation
Thanks to Fabian Brinkmann (Audio Communication Group, TU Berlin) for useful discussions and contributions!
[1] C. Pörschmann*, J.M. Arend*, and F. Brinkmann, “Directional Equalization of Sparse Head-Related Transfer Function Sets for Spatial Upsampling,” IEEE/ACM Trans. Audio, Speech, Lang. Process., vol. 27, no. 6, pp. 1060–1071, 2019, *These authors contributed equally to this work.
[2] C. Pörschmann and J. M. Arend, “A Method for Spatial Upsampling of Directivity Patterns of Human Speakers by Directional Equalization,” in Proceedings of the 45th DAGA, 2019, pp. 1458–1461.
[3] J. M. Arend and C. Pörschmann, “Synthesis of Near-Field HRTFs by Directional Equalization of Far-Field Datasets,” in Proceedings of the 45th DAGA, 2019, pp. 1454–1457.
[4] C. Pörschmann and J. M. Arend, “Obtaining Dense HRTF Sets from Sparse Measurements in Reverberant Environments,” in Proceedings of the AES International Conference on Immersive and Interactive Audio, York, UK, 2019, pp. 1–10.
[5] C. Pörschmann, J. M. Arend, and F. Brinkmann, “Spatial upsampling of individual sparse head-related transfer function sets by directional equalization,” in Proceedings of the 23rd International Congress on Acoustics, 2019, pp. 4870–4877.
[6] J. M. Arend and C. Pörschmann, “Spatial upsampling of sparse head-related transfer function sets by directional equalization - Influence of the spherical sampling scheme,” in Proceedings of the 23rd International Congress on Acoustics, 2019, pp. 2643–2650.
[7] J. M. Arend, F. Brinkmann, and C. Pörschmann, “Assessing Spherical Harmonics Interpolation of Time-Aligned Head-Related Transfer Functions,” J. Audio Eng. Soc., vol. 69, no. 1/2, pp. 104–117, 2021.
[8] C. Pörschmann, J. M. Arend, D. Bau, and T. Lübeck, “Comparison of Spherical Harmonics and Nearest-Neighbor based Interpolation of Head-Related Transfer Functions,” in Proceedings of the AES International Conference on Audio for Virtual and Augmented Reality (AVAR), Redmond, WA, USA, 2020, pp. 1–10.
[9] B. Bernschütz, “Microphone Arrays and Sound Field Decomposition for Dynamic Binaural Recording,” TU Berlin, 2016.
[10] B. Rafaely, Fundamentals of Spherical Array Processing. Berlin Heidelberg: Springer-Verlag, 2015.
[11] J. M. Arend, C. Pörschmann, S. Weinzierl, and F. Brinkmann, “Magnitude-Corrected and Time-Aligned Interpolation of Head-Related Transfer Functions,” IEEE/ACM Trans. Audio Speech Lang. Proc., vol. 31, pp. 3783–3799, 2023.
[12] B. Bernschütz, C. Pörschmann, S. Spors, and S. Weinzierl, “SOFiA Sound Field Analysis Toolbox,” in Proceedings of the International Conference on Spatial Audio - ICSA 2011, 2011, pp. 8–16.
[13] F. Brinkmann and S. Weinzierl, “AKtools - an open software toolbox for signal acquisition, processing, and inspection in acoustics,” in Proceedings of the 142nd AES Convention, Berlin, Germany, 2017, pp. 1–6.
[14] P. Majdak, Y. Iwaya, T. Carpentier, R. Nicol, M. Parmentier, A. Roginska, Y. Suzuki, K. Watanabe, H. Wierstorf, H. Ziegelwanger, and M. Noisternig, “Spatially Oriented Format for Acoustics: A Data Exchange Format Representing Head-Related Transfer Functions,” in Proceedings of the 134th AES Convention, Rome, Italy, 2013, pp. 1–11.
[15] P. Søndergaard and P. Majdak, "The Auditory Modeling Toolbox," in The Technology of Binaural Listening, edited by J. Blauert, Berlin Heidelberg: Springer-Verlag, pp. 33-56, 2013.
[16] H. Wierstorf and S. Spors, "Sound Field Synthesis Toolbox," in Proceedings of the 132th AES Convention, Budapest, Hungary, 2012, pp. 1–4.
[17] Jaroslaw Tuszynski (2021). Triangle/Ray Intersection (https://www.mathworks.com/matlabcentral/fileexchange/33073-triangle-ray-intersection), MATLAB Central File Exchange. Retrieved October 29, 2021.
[18] T. Lübeck, J. M. Arend, and C. Pörschmann, “Spatial Upsampling of Sparse Spherical Microphone Array Signals,” IEEE/ACM Trans. Audio Speech Lang. Proc., vol. 31, pp. 1163–1174, 2023.
[19] J. M. Arend, H. R. Liesefeld, and C. Pörschmann, “On the influence of non-individual binaural cues and the impact of level normalization on auditory distance estimation of nearby sound sources,” Acta Acust., vol. 5, no. 10, pp. 1–21, 2021.
[20] J. M. Arend, M. Ramírez, H. R. Liesefeld, and C. Pörschmann, “Do near-field cues enhance the plausibility of non-individual binaural rendering in a dynamic multimodal virtual acoustic scene?,” Acta Acust., vol. 5, no. 55, pp. 1–14, 2021.