Below is an example of the analysis of electromagnetic waves inside a microwave.
The number of nodes in the microwave analysis is 2494, and the number of elements is 1956. The analysis conditions are as follows: relative permittivity: real part: air 1, dielectric 40; imaginary part: air 0, dielectric -5; relative permeability: real part: air 1, dielectric 1; imaginary part: air 0, dielectric 0. For more details, please download the catalog.
Inquire About This Product
basic information
**Features** ○ Number of nodes: 2494 ○ Number of elements: 1956 ○ Analysis conditions: → Relative permittivity: Real part: Air 1, Dielectric 40; Imaginary part: Air 0, Dielectric -5 Relative permeability: Real part: Air 1, Dielectric 1; Imaginary part: Air 0, Dielectric 0 ○ Boundary conditions: The surface corresponding to the outer perimeter of the microwave oven was treated as a symmetric boundary. ○ Input conditions: Frequency: 2.45 GHz. → The electric field of the introduced microwave varies at each node corresponding to the incident position, with values ranging from 5×10^3 Vm^-1 to 1.0×10^4 Vm^-1 distributed (the Z-axis component of the real part of the electric field vector). ● For more details, please contact us or download the catalog.
Price information
Please contact us.
Delivery Time
※Please contact us.
Applications/Examples of results
For more details, please refer to the catalog or contact us.
catalog(1)
Download All Catalogs![[Analysis Case 5] Product Catalog for Microwave Analysis](https://image.www.ipros.com/public/catalog/image_generated/01/cc2/223741/223741_IPROS6362359955811425063_1.jpg?w=120&h=170)
Company information
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.