Computer Simulation Technology (CST) has announced the addition of Filter Designer 2D to CST Studio Suite, allowing the synthesis, electromagnetic simulation, optimisation and multiphysics analysis of filters in a single environment.
Planar filters are widely used by engineers developing low-cost or compact printed electronics for applications such as networking, communication and signal processing. For these filters, the design process typically has two stages. The first step is selecting an appropriate filter topology from a synthesis tool or textbook and calculating the filter coefficients that match the specification. The second step is analysing and fine-tuning the filter through simulation or prototyping to ensure that it operates correctly when installed.
Built on Nuhertz Technologies’ well-reputed and mature technology, Filter Designer 2D’s integration into CST Studio Suite means the full workflow can now be carried out with a single tool.
Filter Designer 2D includes a database with a wide variety of filter types, including both lumped element and distributed element implementations. Users input the specifications of the filter – including both the frequency response and any physical limitations, such as the maximum size of the filter and the properties of the substrate – and Filter Designer 2D will automatically suggest a design. With a single button click, fully parametric models of this design can be created for either circuit simulation or full-wave 3D simulation.
“Nuhertz has long been a market leader for filter synthesis tools, and we’re proud that our technology has been incorporated into CST Studio Suite,” said Jeff Kahler, president, Nuhertz Technologies. “Through this partnership, we intend to make our technology available to an even wider market of filter designers and engineers.”
With System Assembly and Modeling (SAM), CST’s design automation framework, these models can be simulated and optimised to tune their performance and take into account the unforeseen coupling between elements. SAM can also be used to integrate these filter models into larger systems, and also allows the integration of electromagnetic, thermal and structural simulation for a multiphysics analysis of filter detuning.