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AxiDriver is a BEM simulator. The program calculates the sound pressure in front and to the rear of a loudspeaker-driver with a cone, dome, or piston-type rigid diaphragm radiating from an infinite baffle. The baffle can be extended into waveguides of arbitrary shape, as long as it is axis-symmetric. It is also possible to place reflectors in front of the diaphragm. AxiDriver provides valuable information about the radiation pattern in the near- and far-field. It's great for learning, for understanding what is going on, and helps design speakers. The program is easy to use and intuitive. The axis-symmetric assumption allows for partial analytical solution in 3D which is quickening the calculation. Even if the actual problem is asymmetric then approximate AxiDriver-models can give insights and clues about the radiation pattern. AxiDriver displays the near-field at a single frequency as contours, which are overlayed by a sketch of the driver and its diaphragm. Further, the application allows for broad-band analysis into plots of the spectra of the sound pressure and radiation impedance with the help of Vacs as a graphing server. The acoustics is fully coupled to the mechanical rigid body mode of the driver. The layout of AxiDriver is such, that after solving, the motor parameters can be modified and the result is displayed immediately. For example, you can spin up and down the Bl-factor and see the effect on the response almost in real-time.

AxiDriver is a BEM simulator. The program calculates the sound pressure in front and to the rear of a loudspeaker-driver with a cone, dome, or piston-type rigid diaphragm radiating from an infinite baffle. The baffle can be extended into waveguides of arbitrary shape, as long as it is axis-symmetric. It is also possible to place reflectors in front of the diaphragm. AxiDriver provides valuable information about the radiation pattern in the near- and far-field. It's great for learning, for understanding what is going on, and helps design speakers. The program is easy to use and intuitive. The axis-symmetric assumption allows for partial analytical solution in 3D which is quickening the calculation. Even if the actual problem is asymmetric then approximate AxiDriver-models can give insights and clues about the radiation pattern. AxiDriver displays the near-field at a single frequency as contours, which are overlayed by a sketch of the driver and its diaphragm. Further, the application allows for broad-band analysis into plots of the spectra of the sound pressure and radiation impedance with the help of Vacs as a graphing server. The acoustics is fully coupled to the mechanical rigid body mode of the driver. The layout of AxiDriver is such, that after solving, the motor parameters can be modified and the result is displayed immediately. For example, you can spin up and down the Bl-factor and see the effect on the response almost in real-time.

AutoFEM Thermal Analysis - module provides a calculation of the temperature behaviour of products under the action of sources of heat and radiation. Thermal analysis can be used independently to calculate the temperature and thermal field of the design, as well as in conjunction with static analysis to assess the resulting of thermal deformation. In AutoFEM Thermal Analysis the heat conduction problem has two statement: steady-state thermal conductivity - the calculation of the steady (stationary) temperature fields of structures under the applied thermal boundary conditions; time-dependent thermal conductivity - the calculation of temperature fields of construction is dependent on the time, that is, temperature loads have been made relatively recently, and there is a process of active redistribution of temperature fields; As the boundary conditions are used: temperature, heat flux, convective heat transfer, thermal power, radiation.

AutoFEM Thermal Analysis - module provides a calculation of the temperature behaviour of products under the action of sources of heat and radiation. Thermal analysis can be used independently to calculate the temperature and thermal field of the design, as well as in conjunction with static analysis to assess the resulting of thermal deformation. In AutoFEM Thermal Analysis the heat conduction problem has two statement: steady-state thermal conductivity - the calculation of the steady (stationary) temperature fields of structures under the applied thermal boundary conditions; time-dependent thermal conductivity - the calculation of temperature fields of construction is dependent on the time, that is, temperature loads have been made relatively recently, and there is a process of active redistribution of temperature fields; As the boundary conditions are used: temperature, heat flux, convective heat transfer, thermal power, radiation.

AutoFEM Thermal Analysis - module provides a calculation of the temperature behaviour of products under the action of sources of heat and radiation. Thermal analysis can be used independently to calculate the temperature and thermal field of the design, as well as in conjunction with static analysis to assess the resulting of thermal deformation. In AutoFEM Thermal Analysis the heat conduction problem has two statement: steady-state thermal conductivity - the calculation of the steady (stationary) temperature fields of structures under the applied thermal boundary conditions; time-dependent thermal conductivity - the calculation of temperature fields of construction is dependent on the time, that is, temperature loads have been made relatively recently, and there is a process of active redistribution of temperature fields; As the boundary conditions are used: temperature, heat flux, convective heat transfer, thermal power, radiation.

AutoFEM Thermal Analysis - module provides a calculation of the temperature behaviour of products under the action of sources of heat and radiation. Thermal analysis can be used independently to calculate the temperature and thermal field of the design, as well as in conjunction with static analysis to assess the resulting of thermal deformation. In AutoFEM Thermal Analysis the heat conduction problem has two statement: steady-state thermal conductivity - the calculation of the steady (stationary) temperature fields of structures under the applied thermal boundary conditions; time-dependent thermal conductivity - the calculation of temperature fields of construction is dependent on the time, that is, temperature loads have been made relatively recently, and there is a process of active redistribution of temperature fields; As the boundary conditions are used: temperature, heat flux, convective heat transfer, thermal power, radiation.