## 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
* EM3D_ColdPlasma : Cold magnetised plasma
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)
* EM2Da_ColdPlasma : Cold magnetised plasma
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
* EM2D_ColdPlasma : Cold magnetised plasma
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
* EM1D_ColdPlasma : Cold magnetised plasma
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
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"description": "## Petra-M(RF)\n\nThis module provides various Frequency domain RF interface to Petra-M.\n\n### EM3D : Frequency domain Maxwell equation in 3D\n Domain: \n * EM3D_Anisotropic : tensor dielectric\n * EM3D_Vac : scalar dielectric\n * EM3D_ExtJ : external current\n * EM3D_Div : div J = 0 constraints (add Lagrange multiplier)\n * EM3D_PML : PML cartesian streaching\n * EM3D_ColdPlasma : Cold magnetised plasma\n \n Boundary:\n * EM3D_PEC : Perfect electric conductor\n * EM3D_PMC : Perfect magnetic conductor\n * EM3D_H : Mangetic field boundary\n * EM3D_SurfJ : Surface current\n * EM3D_Port : TE, TEM, Coax port\n * EM3D_PortArray : Array of Ports\n * EM3D_PortLoad : Exteranl load, defined as Smat, to PortBC\n * EM3D_E : Electric field\n * EM3D_Continuity : Continuitiy\n * EM3D_Impedance : Impedance BC Continuitiy (Leontovich)\n\n Pair:\n * EM3D_Floquet : Periodic boundary condition\n\n### EM2Da : Frequency domain Maxwell equation in 2D axissymetric space\n Domain: \n * EM2Da_Anisotropic : tensor dielectric\n * EM2Da_Vac : scalar dielectric\n * EM2Da_ExtJ : external current\n * EM2Da_Div : div J = 0 constraints (add Lagrange multiplier)\n * EM2Da_ColdPlasma : Cold magnetised plasma\n \n Boundary:\n * EM2Da_PEC : Perfect electric conductor\n * EM2Da_PMC : Perfect magnetic conductor\n * EM2Da_H : Mangetic field boundary\n * EM2Da_SurfJ : Surface current\n * EM2Da_Port : TE, TEM, Coax port\n * EM2Da_E : Electric field\n * EM2Da_Continuity : Continuitiy\n\n### EM2D : Frequency domain Maxwell equation in 2D space\n Domain: \n * EM2D_Anisotropic : tensor dielectric\n * EM2D_Vac : scalar dielectric\n * EM2D_ExtJ : external current\n * EM2D_PML : PML cartesian streaching\n * EM2D_ColdPlasma : Cold magnetised plasma\n\n Boundary:\n * EM2D_PEC : Perfect electric conductor\n * EM2D_PMC : Perfect magnetic conductor\n * EM2D_H : Mangetic field boundary \n * EM2D_SurfJ : Surface current (To be implemented)\n * EM2D_Port : TE, TEM, Coax port (To be implemented)\n * EM2D_E : Electric field\n * EM2D_Continuity : Continuitiy\n * EM2D_Impedance : Impedance BC Continuitiy (Leontovich)\n\n Pair:\n * EM2D_Floquet : Periodic boundary condition \n\n### EM1D : Frequency domain Maxwell equation in 1D\n Domain: \n * EM1D_Anisotropic : tensor dielectric\n * EM1D_Vac : scalar dielectric\n * EM1D_ExtJ : external current\n * EM1D_ColdPlasma : Cold magnetised plasma\n \n Boundary:\n * EM1D_PEC : Perfect electric conductor\n * EM1D_PMC : Perfect magnetic conductor\n * EM1D_H : Mangetic field boundary\n * EM1D_Port : Surface current\n * EM1D_E : Electric field\n * EM1D_Continuity : Continuitiy\n\n",
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