Homo Tonalis

<p>Music despite being the first art and the first law of physics mastered by man has not received due attention since ancient Greece particularly with respect to the development and education of children as proposed by Plato in classical Athens. Keep in mind that the tones forming music scales originated from ratios of string segments in the 6th century BC at the hands of Pythagoras who observed an inverse correlation between the length of a string and its vibration frequency. That was how musical tones intervals and scales came about two hundred years before Plato. Music is both science and art. This statement can be confirmed in relation to physics mathematics geometry and biology involving sensory cognitive emotional and social aspects. </p><p>With respect to the statement above it is worth considering the words of Max Planck the father of quantum physics and also an accomplished classical pianist. While discussing the relationship between <em>science</em> and <em>art</em> during an interview with <em>The Observer</em> on January 25 1931 the reporter asked Planck if one was more important than the other to which the physicist replied: It is like asking me which is more important the lock or the key. </p><p>The purpose of this book is the redemption of music's proper status as the first art while unveiling opportunities to use music scientifically in the areas of health and education. Two original theses are integrated into the framework of the book:<em> Homo Tonalis </em>and <em>Spectrogrammatic Entrainment</em>. </p><p><em>Homo Tonalis</em> explains the tonal roots and musical heritage of humans embracing the <em>musical brain model</em>. The thesis explains that the homo Tonalis is born at 24 weeks of gestation when the fetus begins to discern melodies three months before the child is delivered. The thesis is grounded on the observation of neurological preferences and behaviors caused by tonal antecedence in utero which are naturally expressed after birth and remain until old age. </p><p>Secondly the discovery of <em>rhythmic auditory-motor entrainment</em> in clinical populations was a historical breakthrough in demonstrating a neurological mechanism linking music to retraining brain and behavioral functions (Thaut et al. 1998b). Yet little attention has been paid to <em>spectral auditory-neural entrainment</em> implicit in the arresting nature of sound itself. The sound we hear is nothing other than the brain's electrical <em>response</em> to external acoustic stimuli. </p><p>In this regard the <em>spectral</em> content of music (harmony and timbre) is processed by the human brain at a <em>fractal</em> level (harmonics and inharmonics). This indicates ancestry beyond the reach of record suggesting that the neural mechanisms operating the granular processing of music are intrinsic to the nature and growth of the brain. In the final analysis the spectrogrammatics of music is behind the powerful impact on brain function and genetic expression generally attributed to music.</p>