The current research is part of a trans-disciplinary discussion on the long-lasting impact of the acoustic environment on cognitive performance, literacy and auditory perception for preschool children, aiming to underlie the increasing necessity to perfectly tune every-day facilities such as schools and work spaces, rather than only performance auditoriums. The main focus is placed on improving speech intelligibility, which is the task of recognizing the message from the din, by evaluating the speech-in-noise perception. The research is based on a promising hypothesis that hybrid devices should allow for low-frequency absorption and high-frequency diffusion which correspond to certain properties of vowels and consonants respectively. Given the transition to the modern aesthetics of the flat wall, compared to the inherent complexity of surface ornamentation in the past, there is a growing demand to provide acoustic solutions that allow for a higher level of complexity towards an improved acoustic environment. The effect of periodicity on a uniform scattered distribution is investigated by examining different geometrical patterns, aiming to convert traditional materials into sound controlling devices. Customized and mass-produced versions are developed,arguing whether a lower level of complexity can meet the same goals if certain low-level rules with high level of self-organization are applied, introducing the idea of simplicity and architectural smartness by preserving the economy of means for the end users. Last but not least, since speech transmission is related to spatial context and surface properties, both the macro-scale and micro-scale are examined.

The study envisions an open-source toolbox for designers for generating design alternatives providing a deeper understanding on how periodicity affects the acoustics of a given space. Since periodic surfaces reduce the complexity of the reflected sound field, designers are encouraged to focus on a-periodic patterns aiming for a non-repetitive sequence via the geometry articulation.Further it suggests the manipulation of certain parameters, such as period,depth-to-width ratio and well width, towards an integrated workflow to achieve an optimized acoustic design. These alternatives can then be used as input fora software similar to Pachyderm Acoustics plug-in for Grasshopper, in order to get a glimpse which of those showcase a high scattering performance within the relevant frequency range. This should for no reason substitute the necessity for a thorough acoustical study as a next step but would however, involve designers more actively in the initial process of form-finding, while gaining awareness of the impact of their design choices on the acoustic environment.