Digitalización del libro “La música en la Catedral de Santo Domingo de la Calzada

Gonzalo Santamaría; Teresa Cascudo; César Domínguez; Jónathan Heras; Eloy Mata; Vico Pascual; María Villota

doi:10.66737/ier.zub.197

Authors

Gonzalo Santamaría University of La Rioja Author
Teresa Cascudo University of La Rioja Author
César Domínguez University of La Rioja Author
Jónathan Heras University of La Rioja Author
Eloy Mata University of La Rioja Author
Vico Pascual University of La Rioja Author
María Villota University of La Rioja Author

DOI:

https://doi.org/10.66737/ier.zub.197

Keywords:

Rioja musical archive, Artificial Intelligence, Optical Character Recognition, Optical Music Recognition

Abstract

El archivo musical de la Catedral de Santo Domingo, by José López Calo, contains a catalogue of sacred musical compositions such as masses, carols, or psalms composed by different authors. This book did not have a digital version until now; so, its contents could only be accessed through one of the 500 printed copies. The aim of this work is to produce a digital and structured version of the book, in order to conduct text searches, or to consult the works of different authors and/or different musical genres through a web page, as well as to be able to reproduce the melody of these works. This article explains the process followed to reach such an objective. The final result can be found in the following link: https://domingo.unirioja.es/.

Downloads

Download data is not yet available.

References

Adrian Rosebrock, Abhishek Thanki, S. P., y Haase, J. (2020a). OCR with OpenCV, Tesseract and Python - Intro to OCR. PyImageSearch.

Adrian Rosebrock, Abhishek Thanki, S. P., y Haase, J. (2020b). OCR with OpenCV, Tesseract and Python - OCR Practitioner Bundle. PyImage-Search.

Bangare, S., Dubal, A., Bangare, P., y Patil, S. (2015). Reviewing Otsu’s method for image thresholding. International Journal of Applied Engineering Research, 10:21777–21783.

Bisong, E. (2019). Google Colaboratory, pages 59–64. Apress, Berkeley, CA.

Bitteur, H. (2004). Audiveris. https://github.com/audiveris.

Bochkovskiy, A. (2020). Yolo v4, v3 and v2 for Windows and Linux. https://github.com/AlexeyAB/darknet.

Bochkovskiy, A., Wang, C., y Liao, H. M. (2020). Yolov4: Optimal speed and accuracy of object detection. CoRR, abs/2004.10934.

Bradski, A. (2008). Learning OpenCV, Computer Vision with OpenCV Library; software that sees. O‘Reilly Media, 1 ed. edition.

Bradski, G. (2000). The OpenCV Library. Dr. Dobb’s Journal of Software Tools.

Britannica, T. E. (2009). Midi: music technology. Encyclopedia Britannica.

Calvo-Zaragoza, J., Hajič Jr. J., y Pacha, A. (2021). Understanding optical music recognition. ACM Computing Surveys, 53(4), 77, 1–35

Calvo-Zaragoza, J. y Rizo, D. (2018). End-to-end neural optical music recognition of monophonic scores. Applied Sciences, 8(4).

Good, M. (2001a). MusicXML: An internet-friendly format for sheet music. Recordare LLC.

Good, M. (2001b). MusicXML for notation and analysis. Recordare LLC.

Good, M. (2013). MusicXML: The first decade. MakeMusic, Inc., USA.

Hankinson, A., Roland, P., y Fujinaga, I. (2011). The music encoding initiative as a document-encoding framework. pages 293–298.

Howard, J. et al. (2018). fastai. https://github.com/fastai/fastai.

Huang, Z., Jia, X., y Guo, Y. (2019). State-of-the-art model for music object recognition with deep learning. Applied Sciences, 9(13):2645–2665.

Hui, J. (2018). mAP (mean average precision) for object detection. https://jonathan-hui. medium.com/map-mean-average-precision-for-object-detection-45c121a31173.

Jeff Fulton, S. F. (2011). HTML5 Canvas. O’Reilly Media.

Kaiming He, Xiangyu Zhang, S. R. (2015). Resnet-18: Deep residual learning for image recognition. https://www.kaggle.com/pytorch/resnet18.

Lin, T.-Y., Goyal, P., Girshick, R., He, K., y Dollár, P. (2018). Focal loss for dense object detection. https://arxiv.org/abs/1708.02002

Pacha, A. (2017). Optical music recognition datasets. https://github.com/apacha/OMR-Datasets.

Perez, L. y Wang, J. (2017). The effectiveness of data augmentation in image classification using deep learning. CoRR, abs/1712.04621.

Pezoa, F., Reutter, J. L., Suarez, F., Ugarte, M., y Vrgoč, D. (2016). Foundations of JSON schema. In Proceedings of the 25th International Conference on World Wide Web, pages 263–273. International World Wide Web Conferences Steering Committee.

Rebelo, A., Fujinaga, I., Paszkiewicz, F., Marcal, A. R., Guedes, C., y Cardoso, J. d. S. (2012). Optical music recognition: state-of-the-art and open issues. International Journal of Multimedia Information Retrieval, 1(3):173–190.

Ren, S., He, K., Girshick, R. B., y Sun, J. (2015). Faster R-CNN: towards real-time object detection with region proposal networks. CoRR, abs/1506.01497.

Rosebrock, A. (2014). Non-maximum suppression for object detection in python. https://www.pyimagesearch.com/2014/11/17/ non-maximumsuppression-object-detection-python/.

Rosebrock, A. (2016). Intersection over union (IoU) for object detection. https://www.pyimagesearch.com/2016/11/07/intersection-over-unioniou-for-object-detection/.

Roza, F. (2019). End-to-end learning, the (almost) every purpose ml method. https://towardsdatascience.com/e2e-the-every-purpose-ml-method-5d4f-20dafee4

Tan, M., Pang, R., y Le, Q. V. (2019). EfficientDet: Scalable and efficient object detection. CoRR, abs/1911.09070.

Van Rossum, G. y Drake, F. L. (2009). Python 3 Reference Manual. CreateSpace, Scotts Valley, CA.

Vázquez, L. (2020a). IceVision. https://airctic.com/0.8.0/.

Vázquez, L. (2020b). IceVision: An agnostic object detection framework. https://github.com/airctic/icevision.

Yousefi, J. (2015). Image binarization using Otsu thresholding algorithm.

https://www.researchgate.net/publication/277076039_Image_Binarization_using_Otsu_Thresholding_Algorithm