        TY  - JOUR
T1  - A harmonic-based musical scaling method with natural number frequencies
TT  - A harmonic-based musical scaling method with natural number frequencies
AU  - Ozaydin, Selma
PY  - 2025
DA  - March
Y2  - 2025
DO  - 10.12975/rastmd.20251312
JF  - Rast Musicology Journal
JO  - RMD
PB  - Genç Bilge Yayıncılık
WT  - DergiPark
SN  - 2147-7361
SP  - 19
EP  - 37
VL  - 13
IS  - 1
LA  - en
AB  - General acceptance arises from the most convincing method among the available options. Similarly, while the Western chromatic scale is the most widely used system today, it has limitations in representing harmonious intervals, microtonal performances, and the weak resonant effects of fractional frequencies This study introduces the Safir method, a novel approach to redefining musical note frequencies within an octave interval. Unlike traditional scales, Safir employs natural number-based values, ensuring more harmonious intervals and enhanced tuning consistency. A key strength of Safir lies in its ability to overcome the limitations of conventional tuning systems. The Safir method enhances spectral coherence by aligning note frequencies with the harmonic distribution of the Fourier series and strengthening the resonance effect through natural frequencies. This method has significant potential for various applications including music, speech and signal processing, spectral leakage reduction, and healthcare. Four key advantages of the Safir scale system are its its alignment with the harmonic series, , the strong resonant effect of note frequencies derived from natural numbers, the suppression of dissonant intervals in higher frequencies across the octave band, and its linear spacing within the octave, which ensures minimal deviation from compatible intervals even in microtonal divisions. This novel method represents a major advancement in tuning and musical scales. By providing a more precise, harmonious, and resonant frequency system, Safir addresses key shortcomings of traditional musical scales and opens new possibilities in both theoretical and practical domains.
KW  - harmonic frequency analysis
KW  - harmonic scale intervals
KW  - healthcare
KW  - musical scale
KW  - Pythagorean tuning
KW  - temperament systems
N2  - General acceptance arises from the most convincing method among the available options. Similarly, while the Western chromatic scale is the most widely used system today, it has limitations in representing harmonious intervals, microtonal performances, and the weak resonant effects of fractional frequencies This study introduces the Safir method, a novel approach to redefining musical note frequencies within an octave interval. Unlike traditional scales, Safir employs natural number-based values, ensuring more harmonious intervals and enhanced tuning consistency. A key strength of Safir lies in its ability to overcome the limitations of conventional tuning systems. The Safir method enhances spectral coherence by aligning note frequencies with the harmonic distribution of the Fourier series and strengthening the resonance effect through natural frequencies. This method has significant potential for various applications including music, speech and signal processing, spectral leakage reduction, and healthcare. Four key advantages of the Safir scale system are its its alignment with the harmonic series, , the strong resonant effect of note frequencies derived from natural numbers, the suppression of dissonant intervals in higher frequencies across the octave band, and its linear spacing within the octave, which ensures minimal deviation from compatible intervals even in microtonal divisions. This novel method represents a major advancement in tuning and musical scales. By providing a more precise, harmonious, and resonant frequency system, Safir addresses key shortcomings of traditional musical scales and opens new possibilities in both theoretical and practical domains.
CR  - Aktas, M. E., Akbas, E., Papayik, J., &amp; Kovankaya, Y. (2019). Classification of Turkish makam music: A topological approach. Journal of Mathematics and Music, 13(2), 135-149. https://doi.org/10.1080/17459737 .2019.1622810
CR  - Altun, F., &amp; Egermann, H. (2021). Temperament systems influence emotion induction but not makam recognition performance in Turkish makam music. Psychology of Music, 49(5), 1088-1101. https://doi.org/10.1177/0305735620922892
CR  - Álvarez, A., Martínez, R., Gómez, P., Nieto, V., &amp; Rodellar, V. (2007). A robust mel-scale subband voice activity detector for a car platform. Interspeech 2007, pp.226-229. https://doi.org/10.21437/ Interspeech.2007-92
CR  - Ashton-Bell, R. L. T. (2019). On the Geometric Realisation of Equal Tempered Music. Mapana Journal of Sciences, 18(3), 53-75. https:// doi.org/10.12723/mjs.50.5
CR  - Bailes, F., Dean, R. T., &amp; Broughton, M. C. (2015). How Different Are Our Perceptions of Equal-Tempered and Microtonal Intervals? A Behavioural and EEG Survey. PLOS ONE, 10(8), Article no:e0135082. https://doi. org/10.1371/journal.pone.0135082
CR  - Bozkurt, B., Ayangil, R., &amp; Holzapfel, A. (2014). Computational Analysis of Turkish Makam Music: Review of State-of-the-Art and Challenges. Journal of New Music Research, 43(1), 3-23. https://doi.org/10.1080/09298 215.2013.865760
CR  - Brown, J. L. (2016). The Psychological Representation of Musical Intervals in a Twelve-Tone Context. Music Perception, 33(3), 274-286. https://doi.org/10.1525/ mp.2016.33.3.274
CR  - Clader, E. (2018). Why Twelve Tones? The Mathematics of Musical Tuning. The Mathematical Intelligencer, 40(3), 32-36. https://doi.org/10.1007/s00283-017-9759-1
CR  - Crismani, D. J. (2022). The Microtonal String Orchestra. Perspectives of New Music, 60(1), 113-151. https://doi.org/10.1353/ pnm.2022.a902893
CR  - Guers, M. J. (2023). Consistent physical frequencies in time-frequency analysis. The Journal of the Acoustical Society of America, 154(4_supplement), A209-A209. https://doi. org/10.1121/10.0023302
CR  - Hinrichsen, H. (2016). Revising the musical equal temperament. Revista Brasileira de Ensino de Física, 38(1), 1310-1313. https:// doi.org/10.1590/S1806-11173812105
CR  - Ijaz, N., Banoori, F., &amp; Koo, I. (2024). Reshaping Bioacoustics Event Detection: Leveraging Few-Shot Learning (FSL) with Transductive Inference and Data Augmentation. Bioengineering, 11(7), 685-704. https://doi.org/10.3390/ bioengineering11070685
CR  - Isaacson, E. (2023). Visualizing Music. Indiana University Press. https://doi.org/10.2307/ jj.2131181
CR  - Kellermann, W., Martin, R., &amp; Ono, N. (2023). Signal processing and machine learning for speech and audio in acoustic sensor networks. EURASIP Journal on Audio, Speech, and Music Processing, 2023(1), 54, s13636-023-00322-00326. https://doi. org/10.1186/s13636-023-00322-6
CR  - Konar, S. (2019a). The Sounds of Music: Science of Musical Scales: 1. Human Perception of Sound. Resonance, 24(8), 891- 900. https://doi.org/10.1007/s12045-019- 0851-z
CR  - Konar, S. (2019b). The Sounds of Music: Science of Musical Scales: II: Western Classical Music. Resonance, 24(9), 1015- 1023. https://doi.org/10.1007/s12045-019- 0867-4
CR  - Lindley, M. (2001). Just intonation (C.1). Oxford University Press. https:// doi.org/10.1093/gmo/9781561592630. article.1
CR  - Liu, G., Cai, S., &amp; Wang, C. (2023). Speech emotion recognition based on emotion perception. EURASIP Journal on Audio, Speech, and Music Processing, 2023(1), Article no:22. https://doi.org/10.1186/ s13636-023-00289-4
CR  - Moore, B. C. J., Tyler, L. K., &amp; Marslen-Wilson, W. (2008). Introduction. The perception of speech: From sound to meaning. Philosophical Transactions of the Royal Society B: Biological Sciences, 363(1493), 917-921. https://doi.org/10.1098/ rstb.2007.2195
CR  - Parncutt, R. (2024). Psychoacoustic Foundations of Major-Minor Tonality. The MIT Press. https://doi.org/10.7551/ mitpress/15050.001.0001
CR  - Puche-Panadero, R., Martinez-Roman, J., Sapena-Bano, A., Burriel-Valencia, J., Pineda-Sanchez, M., Perez-Cruz, J., &amp; Riera- Guasp, M. (2021). New Method for Spectral Leakage Reduction in the FFT of Stator Currents: Application to the Diagnosis of Bar Breakages in Cage Motors Working at Very Low Slip. IEEE Transactions on Instrumentation and Measurement, 70, 1-11. https://doi. org/10.1109/TIM.2021.3056741
CR  - Schwartz, D. A., Howe, C. Q., &amp; Purves, D. (2003). The Statistical Structure of Human Speech Sounds Predicts Musical Universals. The Journal of Neuroscience, 23(18), 7160-7168. https://doi.org/10.1523/ JNEUROSCI.23-18-07160.2003
CR  - Sereda, M., Xia, J., El Refaie, A., Hall, D. A., &amp; Hoare, D. J. (2018). Sound therapy (using amplification devices and/or sound generators) for tinnitus. Cochrane Database of Systematic Reviews, 12(12). https://doi. org/10.1002/14651858.CD013094.pub2
CR  - Smit, E. A., Milne, A. J., Dean, R. T., &amp; Weidemann, G. (2019), Perception of affect in unfamiliar musical chords. PLOS ONE, 14(6), Article no: e0218570. https://doi. org/10.1371/journal.pone.0218570
CR  - Thoegersen, P. (2024). Maqam Melodies: Pitches, Patterns, and Developments of Music in the Middle East and other Microtonal Writings (1st Ed). Jenny Stanford Publishing. https://doi.org/10.1201/9781003492856
CR  - Uyar, B., Atli, H. S., Şentürk, S., Bozkurt, B., &amp; Serra, X. (2014). A Corpus for Computational 
ResearchofTurkishMakamMusic.Proceedings of the 1st International Workshop on Digital Libraries for Musicology, 1-7. https://doi. org/10.1145/2660168.2660174
CR  - Wang, Y., Chen, K., Gou, X., He, R., Zhou, W., Yang, S., &amp; Qiu, G. (2021). A High- Precision and Wideband Fundamental Frequency Measurement Method for Synchronous Sampling Used in the Power Analyzer. Journal on Frontiers in Energy Research, 9, Article no: 652386. https://doi. org/10.3389/fenrg.2021.652386
CR  - Yost, W. A. (2009). Pitch perception. Attention, Perception &amp; Psychophysics, 71(8), 1701-1715. https://doi.org/10.3758/ APP.71.8.1701
UR  - https://doi.org/10.12975/rastmd.20251312
L1  - https://dergipark.org.tr/en/download/article-file/4455791
ER  -