Analysis of Sound Frequencies: Fundamentals, Applications, and Experiments (Resonance, Particles, and Patterns)

The present research offers a rigorous and interdisciplinary analysis of the concept of frequency, addressing its mathematical definition and its application in key fields such as acoustics, medicine, electronics, physics, and astronomy. Frequency, measured in hertz (Hz), constitutes a fundamental parameter in understanding wave, vibrational, and energetic phenomena. This basic, qualitative, and experimental study was conducted using a descriptive-explanatory design, supported by a systematic review  academic sources, from which  highly relevant articles were selected for theoretical and practical analysis. Principles of resonance and their interaction with material structures were explored through a simple experiment involving a speaker, a membrane made from a balloon fragment, baking soda, and a cardboard tube (60 cm x 8 cm). This setup enabled the visualization of resonance patterns (similar to Chladni figures) within the 100 Hz to 936 Hz range. The results confirm classical theories in acoustics and demonstrate how specific frequencies can induce the spontaneous organization of particles, generating structured patterns. MATLAB will be used to perform graphical and spectral analysis of the observed waveforms, enhancing the scientific visualization of the data. In addition to its pedagogical and technological value, the findings support the growing interest in the therapeutic properties of sound. Various studies indicate that specific frequencies may stimulate cellular repair processes and emotional balance. As a future research direction, it is proposed to evaluate how different geometries and materials influence the formation of complex resonant patterns and their potential bioenergetic properties.