Specify the set of nodes located on the same plane! Calculate the electric field at each node and set it as the load condition.
In "PHOTO-WAVEjω" prior to Ver8.0, it was necessary to set the electric field (3 components) at nodes or the current density (3 components) at elements as load conditions. Since Ver8.2, a feature has been added to automatically set these load conditions. Users can specify a set of nodes that are on the same plane, and by simply entering a few parameters, the program calculates the electric field at each node and sets it as the load condition. [Issues] ■ In "PHOTO-WAVEjω" prior to Ver8.0, it was necessary to set the electric field at nodes or the current density at elements as load conditions. ■ When setting the electric field in a rectangular waveguide, it was necessary to set each electric field component from the coordinate values of each node, which was a cumbersome task for users. *For more details, please refer to the related links or feel free to contact us.
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**Automatic Setting Method for Load Conditions** ■ Specify ports on the nodes of the plane where you want to set the load (electric field) ■ Select either TE wave or TM wave as the mode of the electromagnetic wave you are considering ■ Choose either "maximum electric field" or "power" from the category of parameters ■ Select from the order items how many modes to calculate from the first mode ■ Input the maximum value of the electric field or the power value for the load condition in the "intensity" item ■ Finally, enter the phase value at the port *For more details, please refer to the related links or feel free to contact us.*
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At Photon, we are developing "electromagnetic field analysis software" that models and simulates products and components utilizing electromagnetic phenomena on computers. In traditional design and development environments, the process has primarily revolved around trial and error through prototypes based on the experience of engineers and experiments with those prototypes. However, conducting experiments with actual prototypes and analyzing the results requires significant time and cost. Moving forward, transitioning from an experimental and prototype-based approach to an analysis-based design is a critical issue for improving productivity, and establishing simulation technology as the core of analysis-based design techniques is a challenge. In this context, Photon is developing and providing "analysis software" focusing on electromagnetic fields, as well as heat, vibration, and sound fields. By utilizing Photon’s software, efficient development and design of various industrial products can be achieved. In this way, Photon aims to reduce the number of prototypes and development costs, shorten development periods in the manufacturing sites of our users, and ultimately support the enhancement of our users' competitiveness.
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