Calculation of sound insulation of ribbed panels using statistical energy analysis

In the application of the statistical energy analysis theory to the calculation of sound insulation it has been determined that there is a great discrepancy between the measured and theoretical values at low frequencies. This is one of the disadvantages of statistical energy analysis. Therefore, it

A BS TRA C T Tile method of statistical energy analysis (SEA) has been used to predict the sound .field in rooms containing noise sources. Because SEA takes into account the c, ibration modes both of the boundaries of the room and of the room itself together with the energy transport between them, t

Inclusion of non-resonant component is expected to improve the estimation of response of a structure to acoustic excitation. In this paper this is veri"ed experimentally. A typical plate is subjected to acoustic excitation in a reverberant chamber and the acceleration responses are measured. The exp

The energy ¯ow analysis method was used to predict the structural vibration response and the radiated sound power of a plate excited by wall pressure ¯uctuations under turbulent boundary layers, and separated±reattached ¯ows. This method allows the spatially averaged energy density response to be ca

A method for determining the dissipation and coupling loss factors of a fully assembled machinery structure is presented in this paper. The method is based on the experimental measurements of the total loss factors and the energy ratios between the subsystems of the machine structure when fully asse