@ARTICLE{Qureshi_Tahir_Mushtaq_Non-uniform_2020, author={Qureshi, Tahir Mushtaq and Syed, Khalid Saifullah and Zafar, Asim}, volume={vol. 45}, number={No 4}, journal={Archives of Acoustics}, pages={585-600}, howpublished={online}, year={2020}, publisher={Polish Academy of Sciences, Institute of Fundamental Technological Research, Committee on Acoustics}, abstract={For many years, a digital waveguide model is being used for sound propagation in the modeling of the vocal tract with the structured and uniform mesh of scattering junctions connected by same delay lines. There are many varieties in the formation and layouts of the mesh grid called topologies. Current novel work has been dedicated to the mesh of two-dimensional digital waveguide models of sound propagation in the vocal tract with the structured and non-uniform rectilinear grid in orientation. In this work, there are two types of delay lines: one is called a smaller-delay line and other is called a larger-delay line. The larger-delay lines are the double of the smaller delay lines. The scheme of using the combination of both smaller- and larger-delay lines generates the non-uniform rectilinear two-dimensional waveguide mesh. The advantage of this approach is the ability to get a transfer function without fractional delay. This eliminates the need to get interpolation for the approximation of fractional delay and give efficient simulation for sound wave propagation in the two-dimensional waveguide modeling of the vocal tract. The simulation has been performed by considering the vowels /ɔ/, /a/, /i/ and /u/ in this work. By keeping the same sampling frequency, the standard two-dimensional waveguide model with uniform mesh is considered as our benchmark model. The results and efficiency of the proposed model have compared with our benchmark model.}, type={Article}, title={Non-uniform Rectilinear Grid in the Waveguide Modeling of the Vocal Tract}, URL={http://journals.pan.pl/Content/118236/PDF/aoa.2020.135247.pdf}, doi={10.24425/aoa.2020.135247}, keywords={non-linear mesh, waveguide, delay lines}, }