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A numerical comparison of the Westervelt equation with viscous attenuation and a causal propagation operator
Purrington, Robert D.; Norton, Guy V. - In: Mathematics and Computers in Simulation (MATCOM) 82 (2012) 7, pp. 1287-1297
The Westervelt wave equation can be used to describe non-linear propagation of finite amplitude sound. If one assumes that the medium can be treated as a thermoviscous fluid, a loss mechanism can be incorporated, but such a loss mechanism is not adequate if the medium is dispersive. In order to...
Persistent link: https://www.econbiz.de/10010870091
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Non-quasi-static approach with surface-potential-based MOSFET model HiSIM for RF circuit simulations
Ezaki, T.; Navarro, D.; Takeda, Y.; Sadachika, N.; … - In: Mathematics and Computers in Simulation (MATCOM) 79 (2008) 4, pp. 1096-1106
We develop a non-quasi-static MOSFET compact model suitable for simulating RF circuits operating under GHz frequency. The model takes into account the carrier dynamics by incorporating the time delay for the carriers to form a channel. Both the time-domain and frequency-domain expressions are...
Persistent link: https://www.econbiz.de/10010749047
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Time domain modeling of pulse propagation in non-isotropic dispersive media
Norton, G.; Novarini, J. - In: Mathematics and Computers in Simulation (MATCOM) 69 (2005) 5, pp. 467-476
Acoustic pulse propagation requires the inclusion of attenuation and its causal companion, dispersion when propagation is through a non-ideal fluid medium. For acoustic propagation in a linear medium, Szabo [T.L. Szabo, J. Acoust. Soc. Am., 96 (1994) 491–500] introduced the concept of a...
Persistent link: https://www.econbiz.de/10010749069