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While the frequency dispersion of impedance and dielectric constant of the microstripline are computed, they are not used to compute the losses.
https://github.com/Qucs/qucsator/blob/22126bb9efe0f3d9…
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First thank you for developing these excellent tools!
I am trying to use your models to study the QNMs of polar dielectric structures but I am having some issues getting useful results.
To begin…
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It's different for both, though. With sequential fabricator, I can set the recipe once and it will craft until I leave the machine. Once I've reentered the machine the recipe output is gone and I have…
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Only really needed if we implement more general area lighting, in which case scenes with dielectrics generate caustics which don't resolve well in a uni-directional pathtracer.
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[Down.docx](https://github.com/user-attachments/files/16589289/Down.docx)
Dear author, when I was using the GPU to run the model, I encountered a problem in the documentation, I don't know how to s…
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In physics for numerical simulations we often use complex valued parameters, e.g. dielectric permittivity, impedance, frequency, etc., so it would be natural to support them. At the moment it can be d…
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Somehow related to #94, I was wondering if you think it could be possible to implement the error propagation (on fitting parameters, experimental uncertainties if present/enabled) to the calculated qu…
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For Tutorial 2: pyEPR/_tutorial_notebooks/Tutorial 2. Field calculations - dielectric energy participation ratios (EPRs).ipynb
It should be pyEPR.ansys instead of pyEPR.core, to import Calcobject.
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One could think of using a deterministic model like e.g. the AIEM or others and fit RT1 coefficients to that model.
One could also think of using existing model of dielectric shapes (e..g for veget…
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Defect description:
There is no correct answer for question 3. It show wrong answer for true as well as for false.
Steps to reproduce the issue :
1.Go to this [link](http://mi-iiith.vlabs.ac.in…