Metadata-Version: 2.4
Name: petram_rf
Version: 26.2.7
Summary: PetraM RF physcis package
Author: S. Shiraiwa
Maintainer-email: "S. Shiraiwa" <shiraiwa@princeton.edu>
License-Expression: GPL-3.0-only
Project-URL: Homepage, https://github.com/piScope/Petra-M--RF
Project-URL: Download, https://github.com/piScope/Petra-M--RF
Keywords: scientific computing,python visualzation,finite element method,MFEM
Classifier: Development Status :: 4 - Beta
Classifier: Intended Audience :: Developers
Classifier: Topic :: Scientific/Engineering :: Physics
Classifier: Programming Language :: Python :: 3.11
Classifier: Programming Language :: Python :: 3.12
Classifier: Programming Language :: Python :: 3.13
Requires-Python: >=3.10
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: petram>=26.1.0
Dynamic: license-file

## Petra-M(RF)

This module provides various Frequency domain RF interface to Petra-M.

### EM3D : Frequency domain Maxwell equation in 3D
  Domain:   
 *    EM3D_Anisotropic : tensor dielectric
 *    EM3D_Vac         : scalar dielectric
 *    EM3D_ExtJ        : external current
 *    EM3D_Div         : div J = 0 constraints (add Lagrange multiplier)
 *    EM3D_PML         : PML cartesian streaching
 
  Boundary:
 *    EM3D_PEC         : Perfect electric conductor
 *    EM3D_PMC         : Perfect magnetic conductor
 *    EM3D_H           : Mangetic field boundary
 *    EM3D_SurfJ       : Surface current
 *    EM3D_Port        : TE, TEM, Coax port
 *    EM3D_PortArray   : Array of Ports
 *    EM3D_PortLoad    : Exteranl load, defined as Smat, to PortBC
 *    EM3D_E           : Electric field
 *    EM3D_Continuity  : Continuitiy
 *    EM3D_Impedance   : Impedance BC Continuitiy (Leontovich)

  Pair:
 *    EM3D_Floquet     : Periodic boundary condition

### EM2Da : Frequency domain Maxwell equation in 2D axissymetric space
  Domain:   
 *    EM2Da_Anisotropic : tensor dielectric
 *    EM2Da_Vac         : scalar dielectric
 *    EM2Da_ExtJ        : external current
 *    EM2Da_Div         : div J = 0 constraints (add Lagrange multiplier)
 
  Boundary:
 *    EM2Da_PEC         : Perfect electric conductor
 *    EM2Da_PMC         : Perfect magnetic conductor
 *    EM2Da_H           : Mangetic field boundary
 *    EM2Da_SurfJ       : Surface current
 *    EM2Da_Port        : TE, TEM, Coax port
 *    EM2Da_E           : Electric field
 *    EM2Da_Continuity  : Continuitiy

### EM2D : Frequency domain Maxwell equation in 2D space
  Domain:   
 *    EM2D_Anisotropic : tensor dielectric
 *    EM2D_Vac         : scalar dielectric
 *    EM2D_ExtJ        : external current
 *    EM2D_PML         : PML cartesian streaching

  Boundary:
 *    EM2D_PEC         : Perfect electric conductor
 *    EM2D_PMC         : Perfect magnetic conductor
 *    EM2D_H           : Mangetic field boundary 
 *    EM2D_SurfJ       : Surface current         (To be implemented)
 *    EM2D_Port        : TE, TEM, Coax port      (To be implemented)
 *    EM2D_E           : Electric field
 *    EM2D_Continuity  : Continuitiy
 *    EM2D_Impedance   : Impedance BC Continuitiy (Leontovich)

  Pair:
 *    EM2D_Floquet     : Periodic boundary condition  

### EM1D : Frequency domain Maxwell equation in 1D
  Domain:   
 *    EM1D_Anisotropic : tensor dielectric
 *    EM1D_Vac         : scalar dielectric
 *    EM1D_ExtJ        : external current
 
  Boundary:
 *    EM1D_PEC         : Perfect electric conductor
 *    EM1D_PMC         : Perfect magnetic conductor
 *    EM1D_H           : Mangetic field boundary
 *    EM1D_Port        : Surface current
 *    EM1D_E           : Electric field
 *    EM1D_Continuity  : Continuitiy

