<table>
<tr>
<td>[[image:Cube-icon.png | link=Getting_Started_with_EM.Cube]] [[image:cad-ico.png | link=Building_Geometrical_Constructions_in_CubeCAD]] [[image:fdtd-ico.png | link=EM.Tempo]] [[image:prop-ico.png | link=EM.Terrano]] [[image:static-ico.png | link=EM.Ferma]] [[image:planar-ico.png | link=EM.Picasso]] [[image:metal-ico.png | link=EM.Libera]] [[image:po-ico.png | link=EM.Illumina]]</td>
<tr>
</table>
[[Image:Back_icon.png|30px]] '''[[EM.Cube | Back to EM.Cube Main Page]]'''
<br />
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== Air Bridge Wizard ==
<td>
[[Image:wiz_bridge_picasso.png|thumb|360px|Default air bridge in EM.Picasso.]]
</td>
</tr>
</table>
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== Basic Link Wizard ==
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ICON: [[File:Basic link icon.png]]
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MENU: '''Tools → Propagation Wizards → Basic Link'''
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MODULE(S): [[EM.Terrano]]
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FUNCTION: Creates a standard transmitter and a grid of standard receivers in the project workspace
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NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a basic communication link infrastructure in [[EM.Terrano]]'s project workspace. The link consists of a half-wave dipole transmitter and a rectangular grid of isotropic receivers with parameterized heights and spacing.
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PYTHON COMMAND(S): emag_basic_link(scene_size,tx_h,rx_h,rx_spacing)
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BASIC LINK WIZARD PARAMETERS
{| border="0"
|-
| valign="top"|
|-
{| class="wikitable"
|-
! scope="col"| Parameter Name
! scope="col"| Value Type
! scope="col"| Units
! scope="col"| Default Value
! scope="col"| Notes
|-
! scope="row" | scene_size
| real numeric
| meter
| 250
| total dimensions of the square receiver grid
|-
! scope="row" | tx_h
| real numeric
| meter
| 10
| height of the default transmitter
|-
! scope="row" | rx_h
| real numeric
| meter
| 1.5
| height of the default receivers
|-
! scope="row" | rx_spacing
| real numeric
| meter
| 5
| spacing among the individual receivers
|}
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<table>
<tr>
<td>
[[Image:wiz_basic_link.png|thumb|500px|Default basic link scene in EM.Terrano.]]
</td>
</tr>
</table>
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== Basic Radar Wizard ==
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ICON: [[File:Basic link icon.png]]
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MENU: '''Tools → Propagation Wizards → Basic Radar'''
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MODULE(S): [[EM.Terrano]]
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FUNCTION: Creates a parameterized monostatic radar scene with a collocated point transmitter and receiver and a point scatterer at a certain range
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NOTES, SPECIAL CASES OR EXCEPTIONS: The user can determine the locations of both the radar (transmitter and receiver) and the target. The user can also import a radiation pattern for the radar antenna and rotate the antenna arbitrarily. By default, a 20dB Y-polarized pyramidal horn antenna pointing along the X-axis is assumed. The target is assumed to be a PEC sphere of 1m radius. The user can change the attributes of the target scatterer group from within the wizard including its material composition, or alternatively import either polarimetric scattering matrix or RCS data.
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PYTHON COMMAND(S): emag_basic_radar(target_label,x0,y0,z0,target_type,rad,epsilon,sigma,scat_file1,scat_file2,antenna_label,x1,y1,z1,pattern_file,rot_x,rot_y,rot_z)
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BASIC RADAR WIZARD PARAMETERS
{| border="0"
|-
| valign="top"|
|-
{| class="wikitable"
|-
! scope="col"| Parameter Name
! scope="col"| Value Type
! scope="col"| Units
! scope="col"| Default Value
! scope="col"| Notes
|-
! scope="row" | Radiator Center X
| real numeric
| meter
| 0
| X-coordinate of the radar antenna center
|-
! scope="row" | Radiator Center Y
| real numeric
| meter
| 0
| Y-coordinate of the radar antenna center
|-
! scope="row" | Radiator Center Z
| real numeric
| meter
| 5
| Z-coordinate of the radar antenna center
|-
! scope="row" | X-Rotation Angle
| real numeric
| degree
| 0
| rotation angle of the radar antenna about X-axis
|-
! scope="row" | Y-Rotation Angle
| real numeric
| degree
| 0
| rotation angle of the radar antenna about Y-axis
|-
! scope="row" | Z-Rotation Angle
| real numeric
| degree
| 0
| rotation angle of the radar antenna about Z-axis
|-
! scope="row" | Target Center X
| real numeric
| meter
| 100
| X-coordinate of the radar antenna center
|-
! scope="row" | Target Center Y
| real numeric
| meter
| 0
| Y-coordinate of the radar antenna center
|-
! scope="row" | Target Center Z
| real numeric
| meter
| 5
| Z-coordinate of the radar antenna center
|-
! scope="row" | Target Radius
| real numeric
| meter
| 1
| radius of the spherical target
|}
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<table>
<tr>
<td>
[[Image:wiz_basic_link.png|thumb|500px|Default basic link scene in EM.Terrano.]]
</td>
</tr>
MODULE(S): [[EM.Tempo]], [[EM.Ferma]]
FUNCTION: Creates the parameterized geometry of a coaxial line segment of a specified characteristic impedance with a dielectric core in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]], this wizard creates a one-port open-ended coaxial transmission line segmentof a specified characteristic impedance. In [[EM.Ferma]], it sets up a 2D solution plane for quasi-static analysis of the coaxial transmission line. The radius of the with given inner and outer conductor is determined based on the specified characteristic impedance. It may be replaced by a numeric value insteadradii.
PYTHON COMMAND(S):
emag_coax_2port_tempoemag_coax_tempo(er,z0,r_innerinner_rad,len)
emag_coax_ferma(er,z0inner_rad,r_innerouter_rad)
[[EM.Tempo|EM.TEMPO]] COAXIAL WIZARD PARAMETERS
{| border="0"
|-
| real numeric
| meters
| 0.1
| length of the line segment
|}
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[[EM.Ferma|EM.FERMA]] COAXIAL WIZARD PARAMETERS
{| border="0"
|-
| valign="top"|
|-
{| class="wikitable"
|-
! scope="col"| Parameter Name
! scope="col"| Value Type
! scope="col"| Units
! scope="col"| Default Value
! scope="col"| Notes
|-
! scope="row" | er
| real numeric
| -
| length 2.2 | relative permittivity of the line segment (only in [[EMdielectric core |-! scope="row" | r_inner| real numeric| meters | 0.Tempo]]) 001 | radius of inner conductor |-! scope="row" | r_outer| real numeric| meters | 0.002 | radius of outer conductor
|}
</table>
== Coplanar Waveguide (CPW) Coil Wizard ==
ICON: [[File:cpw1p coil icon.png]]
MENU: '''Tools → Transmission Line Component Wizards → Coplanar WaveguideToroidal Coil'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.PicassoFerma]], [[EM.FermaLibera]]
FUNCTION: Creates the parameterized geometry of a coplanar waveguide segment on toroidal helix coil with a singlegeneralized super-layer dielectric substrate quadratic cross section in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]] and [[EM.PicassoFerma]], this wizard creates turns the toroidal coil into a one-port open-ended CPW transmission line segment. In [[EM.Ferma]], it sets up a 2D solution plane for quasi-static analysis of the CPW transmission linewire current source.
PYTHON COMMAND(S):
emag_cpw_tempoemag_coil(hmajor_rad,erminor_rad_h,strip_widminor_rad_v,slot_widturns,strip_lenorder,sub_len,sub_wid,draw_substratestep)
emag_cpw_picassoemag_coil_ferma(hmajor_rad,erminor_rad_h,wminor_rad_v,sturns,lsorder,lf)Â emag_cpw_ferma(h,er,s,wstep,box_multipliercurrent,draw_substratewire_rad)
CPW COIL WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | hmajor_rad
| real numeric
| meters project units| 0.0015 10 | substrate height (thickness) radius of the circular axis
|-
! scope="row" | er minor_rad_h
| real numeric
| - project units| 2.2 | substrate relative permittivity horizontal radius of the super-quadratic cross section
|-
! scope="row" | strip_widminor_rad_v
| real numeric
| meters project units| 0.002 2 | width vertical radius of the center strip super-quadratic cross section
|-
! scope="row" | slot_widturns| real integer numeric| meters - | 0.002 50 | width total number of the slots turns
|-
! scope="row" | strip_lenorder| real integer numeric| meters
| -
| length 2 | order of the line segment (only in [[EM.Tempo]] & [[EM.Picasso]]) super-quadratic curve, N = 2 produces an ellipse
|-
! scope="row" | sub_lenstep
| real numeric
| meters
| -
| length of substrate (only 0.005 | increment in the interval [[EM.Tempo0, 2*pi]] & [[EM.Ferma]])- determines the resolution of the curve
|-
! scope="row" | sub_widcurrent
| real numeric
| meters Amp | - 1| width of substrate total current flowing through the coil (only in [[EM.Tempo]] & [[EM.Ferma]])
|-
! scope="row" | draw_substratewire_rad| Booleanreal numeric| -project units | True 0.0005 | Adds substrate & ground planeradius of the coil wire (only in [[EM.Ferma]])
|}
<tr>
<td>
[[Image:wiz_cpw_tempowiz_coil_cad.png|thumb|500px|Default coplanar waveguide segment toroidal coil in EM.TempoCubeCAD.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_cpw_picassowiz_coil_ferma.png|thumb|500px|Default coplanar waveguide segment in EM.Picasso.]]</td></tr><tr><td>[[Image:wiz_cpw_ferma.png|thumb|500px|Default 2D coplanar waveguide toroidal coil in EM.Ferma.]]
</td>
</tr>
</table>
== Microstrip Coplanar Waveguide (CPW) Wizard ==
ICON: [[File:us1p cpw1p icon.png]]
MENU: '''Tools → Transmission Line Wizards → Microstrip LineCoplanar Waveguide'''
MODULE(S): [[EM.Tempo]], [[EM.Picasso]], [[EM.Ferma]]
FUNCTION: Creates the parameterized geometry of a microstrip line coplanar waveguide segment of a specified characteristic impedance on a conductor-backed single-layer dielectric substrate in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]] and [[EM.Picasso]], this wizard creates a one-port open-ended microstrip CPW transmission line segment. In [[EM.Ferma]], it sets up a 2D solution plane for quasi-static analysis of the microstrip CPW transmission line. The width of the microstrip line is determined based on the specified characteristic impedance. It may be replaced by a numeric value instead.
PYTHON COMMAND(S):
emag_microstrip_tempoemag_cpw_tempo(h,er,z0center_wid,strip_lenslot_wid,feed_lencenter_len,sub_len,sub_wid,draw_substrate)
emag_microstrip_picassoemag_cpw_picasso(h,er,z0center_wid,strip_lenslot_wid,feed_lencenter_len)
emag_microstrip_fermaemag_cpw_ferma(h,er,z0strip_wid,slot_wid,box_multiplier,draw_substrate)
MICROSTRIP [[EM.Tempo|EM.TEMPO]] CPW WIZARD PARAMETERS
{| border="0"
|-
| substrate relative permittivity
|-
! scope="row" | z0center_wid
| real numeric
| Ohms meters | 50 0.002 | characteristic impedance width of the center strip
|-
! scope="row" | strip_lenslot_wid
| real numeric
| meters
| - 0.002 | length width of the line segment (only in [[EM.Tempo]] & [[EM.Picasso]]) slots
|-
! scope="row" | feed_lencenter_len
| real numeric
| meters
| - 0.05 | length of feed center line (only in [[EM.Tempo]])segment
|-
! scope="row" | sub_len
| real numeric
| meters
| - 0.1| length of substrate (only in [[EM.Tempo]] & [[EM.Ferma]])
|-
! scope="row" | sub_wid
| real numeric
| meters
| - 0.05 | width of substrate (only in [[EM.Tempo]] & [[EM.Ferma]])
|-
! scope="row" | draw_substrate
|}
<table><tr><td>[[Image:wiz_us_tempo.png|thumb|500px|Default microstrip line segment in EM.Tempo.]]</td></tr><tr><td>[[Image:wiz_us_picasso.png|thumb|500px|Default microstrip line segment in EM.Picasso.]]</td></tr><tr><td>[[Image:wiz_us_ferma.png|thumb|500px|Default 2D microstrip line in EM.Ferma.PICASSO]]</td></tr></table> == Two-Port Microstrip Wizard == ICON: [[File:us2p icon.png]]  MENU: '''Tools → Transmission Line Wizards → Two-Port Microstrip Line''' MODULE(S): [[EM.Tempo]], [[EM.Picasso]] FUNCTION: Creates the parameterized geometry of a two-port microstrip line segment of a specified characteristic impedance on a conductor-backed single-layer dielectric substrate in the project workspace NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]], the two ports are placed at the two edges of the substrate. The width of the microstrip lines is determined based on the specified characteristic impedance. It may be replaced by a numeric value instead.   PYTHON COMMAND(S): emag_microstrip_2port_tempo(h,er,z0,strip_len,sub_len,sub_wid,draw_substrate) emag_microstrip_2port_picasso(h,er,z0,strip_len,feed_len)  TWO-PORT MICROSTRIP CPW WIZARD PARAMETERS
{| border="0"
|-
| substrate relative permittivity
|-
! scope="row" | z0center_wid
| real numeric
| Ohms meters | 50 0.002 | characteristic impedance width of center strip
|-
! scope="row" | strip_lenslot_wid
| real numeric
| meters
| 0.002 | width of the slots | - ! scope="row" | center_len| real numeric| meters | 0.05 | length of the center line segment
|-
! scope="row" | feed_len
| real numeric
| meters
| 0.5 * center_len
| length of feed line segment
|}
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[[EM.Ferma|EM.FERMA]] CPW WIZARD PARAMETERS
{| border="0"
|-
| valign="top"|
|-
{| class="wikitable"
|-
! scope="col"| Parameter Name
! scope="col"| Value Type
! scope="col"| Units
! scope="col"| Default Value
! scope="col"| Notes
|-
! scope="row" | h
| real numeric
| meters
| 0.0015
| substrate height (thickness)
|-
! scope="row" | er
| real numeric
| -
| length of feed line (only in [[EM2.Picasso]])2 | substrate relative permittivity
|-
! scope="row" | sub_lenstrip_wid
| real numeric
| meters
| - 0.002 | length width of substrate (only in [[EM.Tempo]])the center strip
|-
! scope="row" | sub_widslot_wid
| real numeric
| meters
| 0.002
| width of the slots
|-
! scope="row" | box_multiplier
| real numeric
| -
| width 10 | ratio of substrate (only in [[EM.Tempo]])width to sum of widths of center strip and two slots
|-
! scope="row" | draw_substrate
<tr>
<td>
[[Image:wiz_us2p_tempowiz_cpw_tempo.png|thumb|500px|Default two-port microstrip line coplanar waveguide segment in EM.Tempo.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_us2p_picassowiz_cpw_picasso.png|thumb|500px|Default two-port microstrip line coplanar waveguide segment in EM.Picasso.]]</td></tr><tr><td>[[Image:wiz_cpw_ferma.png|thumb|500px|Default 2D coplanar waveguide in EM.Ferma.]]
</td>
</tr>
</table>
== Two-Port Coplanar Waveguide (CPW) Cross Slot Antenna Wizard ==
ICON: [[File:cpw2p iconcross_icon.png]]
MENU: '''Tools → Transmission Line Antenna Wizards → Two-Port Coplanar WaveguideCross Slot Antenna'''
MODULE(S): [[EM.Tempo]], [[EM.Picasso]]
FUNCTION: Creates the parameterized geometry of a two-port coplanar waveguide segment on a single-layer dielectric substrate cross slot antenna in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]], the two ports are placed at wizard creates a cross slot antenna on a dielectric substrate. In [[EM.Picasso]], the two edges wizard creates a cross slot antenna on a slot trace. The total length of each slot is set equal to a half the substrateeffective wavelength, which can be changed. This wizard does not provide a default excitation source in either module.
PYTHON COMMAND(S):
emag_cpw_2port_tempoemag_slot_tempo(h,er,strip_wid,slot_wid,strip_len,sub_len,sub_wid,draw_substratesub_size)
emag_cpw_2port_picassoemag_slot_picasso(h,er,w,s,ls,lfslot_wid)
TWO-PORT CPW CROSS SLOT ANTENNA WIZARD PARAMETERS
{| border="0"
|-
! scope="row" | h
| real numeric
| meters meter| 0.0015 | substrate height (thickness(height)
|-
! scope="row" | er
| real numeric
| -
| 2.2
| substrate relative permittivity
|-
! scope="row" | strip_wid
| real numeric
| meters
| 0.002
| width of the center strip
|-
! scope="row" | slot_wid
| real numeric
| meters meter| 0.002 005| width of the slots slot
|-
! scope="row" | strip_lensub_size
| real numeric
| meters meter| - 0.2| length dimensions of the line segment |-! scope="row" | sub_len| real numeric| meters | - | length of square substrate & ground (only in [[EM.Tempo]])|-! scope="row" | sub_wid| real numeric| meters | - | width of substrate (only in [[EM.Tempo]])|-! scope="row" | draw_substrate| Boolean| -| True | Adds substrate & ground plane
|}
<table>
<tr>
<td>
[[Image:wiz_cpw2p_tempowiz_cross_tempo.png|thumb|500px|Default two-port coplanar waveguide segment cross slot antenna in EM.Tempo.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_cpw2p_picassowiz_cross_picasso.png|thumb|500px|Default two-port coplanar waveguide segment cross slot antenna in EM.Picasso.]]
</td>
</tr>
</table>
== Two-Port Coaxial Cross Slot Wizard ==
ICON: [[File:coax2p iconcross_icon.png]]
MENU: '''Tools → Transmission Line Antenna Wizards → Two-Port Coaxial LineCross Slot'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.TempoIllumina]], [[EM.Ferma]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a two-port coaxial line segment of narrow cross slot in a specified characteristic impedance with a dielectric core in the project workspaceground plane
NOTES, SPECIAL CASES OR EXCEPTIONS: The radius of the outer conductor is determined based on the specified characteristic impedance. It may be replaced by This wizard simply creates a cross slot in a numeric value insteadground plane using Boolean subtraction.
PYTHON COMMAND(S): emag_coax_2port_tempoemag_cross_slot(erslot_len,z0slot_wid,r_inner,lenmetal_size)
TWO-PORT COAXIAL LINEAR SLOT WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | er slot_len
| real numeric
| - project units| 2.2 100| relative permittivity total length of the dielectric core each slot arm
|-
! scope="row" | z0slot_wid
| real numeric
| Ohms project units| 50 10| characteristic impedance total width of each slot arm
|-
! scope="row" | r_innermetal_size
| real numeric
| meters project units| 0.001 200| radius of inner conductor |-! scope="row" | len| real numeric| meters | - | length dimensions of the line segment (only in [[EM.Tempo]]) square metal ground
|}
<tr>
<td>
[[Image:wiz_coax2p_tempowiz_cross_cad.png|thumb|500px|Default two-port coaxial line segment cross slot in EM.TempoCubeCAD.]]
</td>
</tr>
</table>
== Rectangular Waveguide Dipole Antenna Wizard ==
ICON: [[File:wg1p dipole icon.png]]
MENU: '''Tools → Transmission Line Antenna Wizards → Rectangular WaveguideWire Dipole Antenna'''
MODULE(S): [[EM.Tempo]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a rectangular waveguide segment slightly above the cutoff at the center frequency of dipole antenna in the projectworkspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a one-port open-ended rectangular waveguide segment in In [[EM.Tempo]]. The width of , the waveguide is set slightly larger than half its cutoff wavelength for the dominant TE10 modedipole consists of two thin PEC cylinders fed by a lumped source on a short joining line. The height is set equal to half its widthIn [[EM. Both Libera]], the width and height can be replaced by arbitrary numeric valuesdipole is a thin wire.
PYTHON COMMAND(S): emag_rect_waveguide(wg_len,port_offset)
emag_dipole_tempo(len_lambda,wire_rad_lambda)
WAVEGUIDE emag_dipole_libera(len_lambda,wire_rad_lambda)Â Â DIPOLE WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | wg_lenlen_lambda
| real numeric
| meters -| - 0.5 (in [[EM.Libera]]) or 0.47 (in [[EM.Tempo]])| length of the waveguide segment dipole normalized to free-space wavelength
|-
! scope="row" | port_offsetwire_rad_lambda
| real numeric
| meters -| - 0.002 | distance between port plane and the first open end of the waveguide wire radius normalized to free-space wavelength
|}
<tr>
<td>
[[Image:wiz_wg_tempowiz_dipole_tempo.png|thumb|500px300px|Default rectangular waveguide segment with a shorted end wall cylindrical dipole antenna in EM.Tempo.]]</td></tr><tr><td>[[Image:wiz_dipole_libera.png|thumb|300px|Default thin wire dipole antenna in EM.Libera.]]
</td>
</tr>
</table>
== Two-Port Rectangular Waveguide Dipole Array Wizard ==
ICON: [[File:wg2p dpl_array icon.png]]
MENU: '''Tools → Transmission Line Antenna Wizards → Two-Port Rectangular WaveguideWire Dipole Array'''
MODULE(S): [[EM.TempoLibera]]
FUNCTION: Creates the parameterized geometry of a two-port rectangular waveguide segment slightly above the cutoff at the center frequency of dipole antenna array in the projectworkspace
NOTES, SPECIAL CASES OR EXCEPTIONS: The width of the waveguide is set slightly larger than half its cutoff wavelength for the dominant TE10 mode. The height is set equal to half its width. Both the width and height can be replaced by arbitrary numeric valuesdipole elements are all thin wires.
PYTHON COMMAND(S): emag_rect_waveguide_2portemag_dipole_array(wg_lenlen_lambda,feed_lenspacing_lambda,port_offsetnx,ny,wire_rad_lambda)
TWO-PORT WAVEGUIDE DIPOLE ARRAY WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | wg_lenlen_lambda
| real numeric
| meters -| - 0.5 | length of the middle waveguide segment dipole normalized to free-space wavelength
|-
! scope="row" | feed_lenspacing_lambda
| real numeric
| meters -| - 0.5 | length of the feed waveguide segments element spacing normalized to free-space wavelength
|-
! scope="row" | port_offsetnx| integer numeric| -| 5 | number of elements along X |-! scope="row" | ny| integer numeric| -| 1 | number of elements along Y |-! scope="row" | wire_rad_lambda
| real numeric
| meters -| - 0.002 | distance between port planes and the open ends of the waveguide wire radius normalized to free-space wavelength
|}
<tr>
<td>
[[Image:wiz_wg2p_tempowiz_dipole_array.png|thumb|500px|Default two-port rectangular waveguide segment thin wire dipole array in EM.Tempo with the two open-end feed sections in the freeze stateLibera.]]
</td>
</tr>
</table>
== Solenoid Foil Wizard ==
ICON: [[File:solenoid foil icon.png]]
MENU: '''Tools → Component Wizards → SolenoidConformal Coil'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Illumina]], [[EM.Ferma]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a solenoid with a generalized super-quadratic cross cylindrical foil section in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.FermaTempo]], this wizard turns the solenoid into creates a wire current sourceconformal metallic patch on a cylindrical dielectric coating around a cylindrical metal core. In all other modules, it creates a free-standing sectorial cylindrical foil.
PYTHON COMMAND(S):
emag_solenoidemag_foil(major_radfoil_rad,minor_radfoil_height,height,turns,order,stepalpha)
emag_solenoid_fermaemag_foil_tempo(major_rader,minor_radcore_rad,heightfoil_rad,turnscore_height,orderfoil_height,stepfoil_offset,current,wire_radalpha)
SOLENOID FOIL WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | major_rader | real numeric| - | 2.2 | relative permittivity of the dielectric coating (only in [[EM.Tempo]]) |-! scope="row" | core_rad
| real numeric
| project units
| 2 20 | major radius of the super-quadratic cross section metal core (only in [[EM.Tempo]])
|-
! scope="row" | minor_radfoil_rad
| real numeric
| project units
| 2 25 (in [[EM.Tempo]]) or 100 (all others)| minor radius of the super-quadratic cross foil section
|-
! scope="row" | heightcore_height
| real numeric
| project units | 10 50 | total height of the solenoid metal core (only in [[EM.Tempo]])
|-
! scope="row" | turns| integer numeric| - | 10 | total number of turns|-! scope="row" | order| integer numeric| - | 2 | order of the super-quadratic curve, N = 2 produces an ellipse|-! scope="row" | stepfoil_height
| real numeric
| - project units| 0.005 | increment 25 (in the interval [0, 2*pi[EM.Tempo] - determines the resolution ]) or 100 (in all others)| height of the curve foil section
|-
! scope="row" | currentfoil_offset
| real numeric
| Amp project units| 110 | total current flowing through offset of the solenoid foil section with respect to the base of metal core (only in [[EM.FermaTempo]])
|-
! scope="row" | wire_radalpha
| real numeric
| project units degrees | 0.0005 90 | radius of the solenoid wire (only in [[EM.Ferma]])sectoral angle
|}
<tr>
<td>
[[Image:wiz_solenoid_cadwiz_foil_cad.png|thumb|360px|Default solenoid foil section in CubeCAD.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_solenoid_fermawiz_foil_tempo.png|thumb|360px|Default solenoid conformal foil section in EM.FermaTempo.]]
</td>
</tr>
</table>
== Coil Hilly Terrain Wizard ==
ICON: [[File:coil iconhill_icon.png]]
MENU: '''Tools → Component Propagation Wizards → Toroidal CoilHilly Terrain'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Ferma]], [[EM.LiberaTerrano]]
FUNCTION: Creates the parameterized geometry of a toroidal helix coil hilly terrain with a generalized super-quadratic cross section random rough surface in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Ferma]], this This wizard turns the toroidal coil into creates a wire current sourcehilly terrain using a surface object generated with a Gaussian profile. The surface is then roughened based on the specified statistics.
PYTHON COMMAND(S): emag_hill(area_size,height,radius,elevation,res,rms_height,correl_len)
emag_coil(major_rad,minor_rad_h,minor_rad_v,turns,order,step)
emag_coil_ferma(major_rad,minor_rad_h,minor_rad_v,turns,order,step,current,wire_rad)Â Â COIL HILLY TERRAIN WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | major_radarea_size
| real numeric
| project unitsmeter| 10 50| radius dimensions of the circular axis square terrain surface
|-
! scope="row" | minor_rad_hheight
| real numeric
| project unitsmeter| 2 15| horizontal radius height of the super-quadratic cross section hill
|-
! scope="row" | minor_rad_vradius
| real numeric
| project unitsmeter| 2 20| vertical radius of the super-quadratic cross section Gaussian surface profile
|-
! scope="row" | turnselevation| integer real numeric| - meter| 50 1| total number base elevation of turnswhole terrain surface
|-
! scope="row" | order| integer numeric| - | 2 | order of the super-quadratic curve, N = 2 produces an ellipse|-! scope="row" | stepres
| real numeric
| - meter| 0.005 5| increment in the interval [0, 2*pi] - determines the resolution of the curve terrain surface
|-
! scope="row" | currentrms_height
| real numeric
| Amp meter
| 1
| total current flowing through RMS height of the coil (only in [[EM.Ferma]])random rough surface
|-
! scope="row" | wire_radcorrel_len
| real numeric
| project units meter| 0.0005 5| radius correlation length of the coil wire (only in [[EM.Ferma]])random rough surface
|}
<tr>
<td>
[[Image:wiz_coil_cadwiz_hill.png|thumb|500px|Default toroidal coil in CubeCAD.]]</td></tr><tr><td>[[Image:wiz_coil_ferma.png|thumb|500px|Default toroidal coil hilly terrain in EM.FermaTerrano.]]
</td>
</tr>
</table>
== Foil Horn Antenna Array Wizard ==
ICON: [[File:foil iconhorn_array_icon.png]]
MENU: '''Tools → Component Antenna Wizards → Conformal CoilHorn Antenna Array'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Illumina]], [[EM.Ferma]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a cylindrical foil section pyramidal horn antenna array in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]], this This wizard creates an array of pyramidal horn antennas fed by rectangular waveguides with a conformal metallic patch TE10 modal excitation. The larger dimension of each feeding waveguide is set slightly larger than half its cutoff wavelength for the dominant TE10 mode. The aspect ratio of each waveguide's cross section is 2:1. Its length is set to half the free-space wavelength. All of these dimensions can be replaced by arbitrary numeric values. The horn aperture dimensions and its overall length are calculated based on a cylindrical dielectric coating around a cylindrical metal corethe specified antenna gain. In all other modulesAll of these dimensions can be changed, it creates a free-standing sectorial cylindrical foiltoo.
PYTHON COMMAND(S): emag_horn_array(gain_dB,nx,ny,spacing_x_lambda,spacing_y_lambda)
emag_foil(foil_rad,foil_height,alpha)
emag_foil_tempo(er,core_rad,foil_rad,core_height,foil_height,foil_offset,alpha)Â Â FOIL CROSS SLOT ANTENNA WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | er gain_dB
| real numeric
| - | 2.2 15| relative permittivity gain of the dielectric coating (only in [[EM.Tempo]]) each individual horn element
|-
! scope="row" | core_radnx| real integer numeric| project units-| 20 2 | radius number of the metal core (only in [[EM.Tempo]]) elements along X
|-
! scope="row" | foil_radny| real integer numeric| project units-| 25 (in [[EM.Tempo]]) or 100 (all others)2 | radius number of the foil section elements along Y
|-
! scope="row" | core_heightspacing_x_lambda
| real numeric
| project units-| 50 3| height of the metal core (only in [[EM.Tempo]]) element spacing along X normalized to free-space wavelength
|-
! scope="row" | foil_heightspacing_y_lambda
| real numeric
| project units| 25 (in [[EM.Tempo]]) or 100 (in all others)| height of the foil section |-! scope="row" | foil_offset3| real numeric| project units| 10 | offset of the foil section with respect element spacing along Y normalized to the base of metal core (only in [[EM.Tempo]]) |free-! scope="row" | alpha| real numeric| degrees | 90 | sectoral anglespace wavelength
|}
<tr>
<td>
[[Image:wiz_foil_cadwiz_horn_array.png|thumb|360px500px|Default foil section horn antenna array in CubeCADEM.Tempo.]]
</td>
</tr>
</table>
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== Horn Antenna Wizard ==
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ICON: [[File:horn_icon.png]]
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MENU: '''Tools → Antenna Wizards → Horn Antenna'''
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MODULE(S): [[EM.Tempo]]
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FUNCTION: Creates the parameterized geometry of a pyramidal horn antenna in the project workspace
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NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a pyramidal horn antenna fed by a rectangular waveguide with a TE10 modal excitation. The larger dimension of the feeding waveguide is set slightly larger than half its cutoff wavelength for the dominant TE10 mode. The aspect ratio of the waveguide's cross section is 2:1. Its length is set to half the free-space wavelength. All of these dimensions can be replaced by arbitrary numeric values. The horn aperture dimensions and its overall length are calculated based on the specified antenna gain. All of these dimensions can be changed, too.
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PYTHON COMMAND(S): emag_horn(gain_dB)
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HORN ANTENNA WIZARD PARAMETERS
{| border="0"
|-
| valign="top"|
|-
{| class="wikitable"
|-
! scope="col"| Parameter Name
! scope="col"| Value Type
! scope="col"| Units
! scope="col"| Default Value
! scope="col"| Notes
|-
! scope="row" | gain_dB
| real numeric
| -
| 15
| gain of the horn antenna
|}
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<table>
<tr>
<td>
[[Image:wiz_foil_tempowiz_horn.png|thumb|360px500px|Default conformal foil section horn antenna in EM.Tempo.]]
</td>
</tr>
</table>
== Parabolic Reflector Linear Slot Array Wizard ==
ICON: [[File:dish iconslot_array_icon.png]]
MENU: '''Tools → Component Antenna Wizards → Parabolic ReflectorLinear Slot Array'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Illumina]], [[EM.Ferma]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a parabolic reflector an array of narrow rectangular slots in the project workspacea ground plane
NOTES, SPECIAL CASES OR EXCEPTIONS: The aperture diameter This wizard simply creates an array of the reflector is determined based on the focal and axial lengths of the primitive parabolalinear slots in a ground plane using Boolean subtraction.
PYTHON COMMAND(S): emag_parabolic_reflectoremag_linear_slot_array(focal_lenslot_len,axial_lenslot_wid,nx,ny,spacing_x,spacing_y)
PARABOLIC REFLECTOR LINEAR SLOT ARRAY WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | focal_lenslot_len
| real numeric
| project units
| 50100| focal length of the primitive parabola slot
|-
! scope="row" | axial_lenslot_wid
| real numeric
| project units
| 70 10| axial length width of the primitive parabola slot |-! scope="row" | nx| integer numeric| -| 2 | number of elements along X |-! scope="row" | ny| integer numeric| -| 2 | number of elements along Y |-! scope="row" | spacing_x| real numeric| -| 150| element spacing along X|-! scope="row" | spacing_y| real numeric| -| 150| element spacing along Y
|}
<tr>
<td>
[[Image:wiz_dish_tempowiz_slot_array_cad.png|thumb|360px500px|Default parabolic reflector linear slot array in EM.TempoCubeCAD.]]
</td>
</tr>
</table>
== Trihedral Reflector Linear Slot Wizard ==
ICON: [[File:trihed iconslot_icon.png]]
MENU: '''Tools → Component Antenna Wizards → Trihedral ReflectorLinear Slot'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Illumina]], [[EM.Ferma]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a Trihedral corner reflector narrow rectangular slot in the project workspacea ground plane
NOTES, SPECIAL CASES OR EXCEPTIONS: The aperture diameter of the reflector is determined based on the focal and axial lengths of the primitive parabolaThis wizard simply creates a linear slot in a ground plane using Boolean subtraction.
PYTHON COMMAND(S): emag_trihedral_reflectoremag_linear_slot(sideslot_len,slot_wid,metal_size)
TRIHEDRAL REFLECTOR LINEAR SLOT WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | sideslot_len
| real numeric
| project units
| 100
| square wall length of the slot |-! scope="row" | slot_wid| real numeric| project units| 10| width of the slot |-! scope="row" | metal_size| real numeric| project units| 200| dimensions of the square metal ground
|}
<tr>
<td>
[[Image:wiz_trihed_tempowiz_slot_cad.png|thumb|360px500px|Default trihedral reflector linear slot in EM.TempoCubeCAD.]]
</td>
</tr>
</table>
== Particle Cloud Microstrip Wizard ==
ICON: [[File:cloud us1p icon.png]]
MENU: '''Tools → Component Transmission Line Wizards → Particle CloudMicrostrip Line'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.IlluminaPicasso]], [[EM.Ferma]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a random cloud of regular polygon particles contained microstrip line segment on a conductor-backed single-layer dielectric substrate in an ellipsoid regionthe project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: The aperture diameter In [[EM.Tempo]] and [[EM.Picasso]], this wizard creates a one-port open-ended microstrip transmission line segment of the reflector is determined based on the focal and axial lengths a specified characteristic impedance. In [[EM.Ferma]], it sets up a 2D solution plane for quasi-static analysis of the primitive parabolamicrostrip transmission line with a given strip width.
PYTHON COMMAND(S):
emag_particle_cloudemag_microstrip_tempo(n_sidesh,side_lengther,cont_radius_xz0,cont_radius_ycetner_len,cont_radius_zsub_len,n_elementssub_wid,draw_substrate)
emag_particle_cloud_cademag_microstrip_picasso(n_sidesh,side_lengther,cont_radius_xz0,cont_radius_ycenter_len,cont_radius_z,n_elementsfeed_len)
emag_microstrip_ferma(h,er,strip_wid,box_multiplier,draw_substrate)
PARTICLE CLOUD [[EM.Tempo|EM.TEMPO]] MICROSTRIP WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | n_sidesh| integer real numeric| meters | 0.0015 | substrate height (thickness) |-! scope="row" | er | real numeric| - | 2.2 | substrate relative permittivity |-! scope="row" | z0| real numeric| Ohms | 50 | characteristic impedance |-! scope="row" | center_len| real numeric| meters | 0.03| length of center line segment |-! scope="row" | sub_len| real numeric| meters | 0.1 | length of substrate |-! scope="row" | sub_wid| real numeric| meters | 0.05 | width of substrate |-! scope="row" | draw_substrate| Boolean
| -
| 4True | number of sides of the regular polygon particle Adds substrate & ground plane|}Â [[EM.Picasso|EM.PICASSO]] MICROSTRIP WIZARD PARAMETERS{| border="0"
|-
| valign="top"||-{| class="wikitable"|-! scope="col"| Parameter Name! scope="col"| Value Type! scope="col"| Units! scope="col"| Default Value! scope="col"| Notes|-! scope="row" | side_lengthh
| real numeric
| project unitsmeters | 20.0015 | side length of the regular polygon particle substrate height (thickness)
|-
! scope="row" | cont_radius_xer
| real numeric
| project units- | 2002.2 | radius of the ellipsoid container along X substrate relative permittivity
|-
! scope="row" | cont_radius_yz0
| real numeric
| project unitsOhms | 20050 | radius of the ellipsoid container along Y characteristic impedance
|-
! scope="row" | cont_radius_zcenter_len
| real numeric
| project unitsmeters | 1000.03| radius length of the ellipsoid container along Z line segment
|-
! scope="row" | n_elementsfeed_len| integer real numeric| meters | 0.5 * center_len | length of feed line segment|}Â [[EM.Ferma|EM.FERMA]] MICROSTRIP WIZARD PARAMETERS{| border="0"|-| valign="top"||-{| class="wikitable"|-! scope="col"| Parameter Name! scope="col"| Value Type! scope="col"| Units! scope="col"| Default Value! scope="col"| Notes|-! scope="row" | h| real numeric| meters | 0.0015 | substrate height (thickness) |-! scope="row" | er | real numeric| - | 2.2 | substrate relative permittivity |-! scope="row" | strip_wid| real numeric| meters| 2| width of microstrip line |-! scope="row" | box_multiplier| real numeric| - | 10 | ratio of width of substrate to strip width |-! scope="row" | draw_substrate| Boolean
| -
| 100True | total number of particles Adds substrate & ground plane
|}
<tr>
<td>
[[Image:wiz_cloud_tempowiz_us_tempo.png|thumb|500px|Default particle cloud microstrip line segment in EM.Tempo with the ellipsoid container .]]</td></tr><tr><td>[[Image:wiz_us_picasso.png|thumb|500px|Default microstrip line segment in the freeze stateEM.Picasso.]]</td></tr><tr><td>[[Image:wiz_us_ferma.png|thumb|500px|Default 2D microstrip line in EM.Ferma.]]
</td>
</tr>
</table>
== Sierpinski Microstrip-Fed Patch Wizard ==
ICON: [[File:sierpin iconus_patch_icon.png]]
MENU: '''Tools → Component Antenna Wizards → Sierpinski StripMicrostrip-Fed Patch Antenna'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Illumina]], [[EM.Ferma]], [[EM.Picasso]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a Sierpinski triangle fractal microstrip-fed rectangular patch antenna in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: A dialog The wizard asks you to enter values for the key size and number of fractal levelswhether you want a microstrip-fed patch antenna with a recessed feed or one with a direct microstrip line junction. The wizard creates In [[EM.Tempo]], the Sierpinski triangle as feed line is excited by a large set of smaller trianglesmicrostrip port. In [[EM.Picasso]], which cannot be modified using variables afterwardsthe feed line has a scattering wave port. You may want to group The total dimensions of the square patch are set of all equal to 0.5 times the triangles as a single composite objecteffective dielectric wavelength, which can be changed.
PYTHON COMMAND(S): emag_sierpinski(key_size,levels)
emag_microstrip_fed_patch_tempo(is_recess,h,er,z0,feed_len,recess_dep,recess_wid,sub_len,sub_wid)
SIERPINSKI emag_microstrip_fed_patch_picasso(is_recess,h,er,z0,feed_len,recess_dep,recess_wid)Â Â MICROSTRIP-FED PATCH WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | key_sizeis_recess| Boolean| -| True| Creates a recessed feed vs. a direct microstrip line junction to the patch |-! scope="row" | h
| real numeric
| project unitsmeter| 1000.0015| side length of the largest substrate thickness (outermostheight) triangle
|-
! scope="row" | levelser| integer real numeric
| -
| 32.2 | number substrate relative permittivity |-! scope="row" | z0| real numeric| Ohms| 50 | characteristic impedance of fractal levels the microstrip feed |-! scope="row" | feed_len| real numeric| meter| 0.075| length of the microstrip feed line |-! scope="row" | recess_dep| real numeric| meter| 0.015| depth of the feed recess |-! scope="row" | recess_wid| real numeric| meter| 0.005| width of the recess gaps |-! scope="row" | sub_len| real numeric| meter| 0.3| substrate dimension along X (only in [[EM.Tempo]])|-! scope="row" | sub_wid| real numeric| meter| 0.3| substrate dimension along Y (only in [[EM.Tempo]])
|}
<tr>
<td>
[[Image:wiz_sierpin_tempowiz_us_patch_tempo.png|thumb|500px|Default Sierpinski triangle strip microstrip-fed patch antenna in EM.Tempo.]]</td></tr><tr><td>[[Image:wiz_us_patch_picasso.png|thumb|500px|Default microstrip-fed patch antenna in EM.Picasso.]]</td></tr><tr><td>[[Image:wiz_us_patch_recess_tempo.png|thumb|500px|Default microstrip-fed patch antenna with a recessed feed in EM.Tempo.]]</td></tr><tr><td>[[Image:wiz_us_patch_recess_picasso.png|thumb|500px|Default microstrip-fed patch antenna with a recessed feed in EM.Picasso.]]
</td>
</tr>
</table>
== Dipole Antenna Mobile Path Wizard ==
ICON: [[File:dipole Mobile Path icon.png]]
MENU: '''Tools → Antenna Propagation Wizards → Wire Dipole AntennaMobile Path'''
MODULE(S): [[EM.Tempo]], [[EM.LiberaTerrano]]
FUNCTION: Creates the parameterized geometry of a dipole antenna mobile path of transmitters or receivers in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]], the dipole consists This wizard creates either a set of two thin PEC cylinders fed by transmitters or a lumped source on set of receivers along a short joining linespecified path. In [[EMThe path can be specified in one of three different ways: (a) using an existing "virtual" nodal curve, i.Libera]]e. a polyline or a NURBS curve, whose nodes define the dipole is base locations, (b) using an existing "virtual" line object by specifying the number of base location points, and (c) using an existing spatial Cartesian data file, which specifies the coordinates of the base location points. The Mobile Path Wizard provides a thin wirelist of all the nodal curves or line objects that have been defined as virtual objects in the project workspace.
PYTHON COMMAND(S):
emag_dipole_tempoemag_mobile_path_nodal(len_lambdalabel,wire_rad_lambdanodal_curve,TxRx=0)
emag_dipole_liberaemag_mobile_path_line(len_lambdalabel,wire_rad_lambdaline_object,num_points=10,TxRx=0)
emag_mobile_path_file(label,file_name,TxRx=0)
DIPOLE MOBILE PATH WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | len_lambdanodal_curve| real numericstring
| -
| 0.5 (in [[EM.Libera]]) or 0.47 (in [[EM.Tempo]])-| length name of dipole normalized to free-space wavelength the nodal curve object
|-
! scope="row" | wire_rad_lambdaTxRx| real numericinteger
| -
| 0.002 | wire radius normalized to freeenter 0 for transmitters and 1 for receivers|-space wavelength ! scope="row" | line_object| string| -| -| name of line object|-! scope="row" | file_name| string| -| -| the name of spatial Cartesian data file that must have a ".CAR" file extension
|}
<tr>
<td>
[[Image:wiz_dipole_tempoWiz mobile1.png|thumb|300px480px|Default cylindrical dipole antenna in EM.TempoThe mobile path wizard dialog.]]
</td>
</tr>
</table>
<table>
<tr>
<td>
[[Image:wiz_dipole_liberaWiz mobile2.png|thumb|300px640px|Default thin wire dipole antenna in EM.LiberaA set of transmitters created from a virtual polyline object using the mobile path wizard.]]
</td>
</tr>
</table>
== Dipole Array Mountainous Terrain Wizard ==
ICON: [[File:dpl_array iconmountain_icon.png]]
MENU: '''Tools → Antenna Propagation Wizards → Wire Dipole ArrayMountainous Terrain'''
MODULE(S): [[EM.LiberaTerrano]]
FUNCTION: Creates the parameterized geometry of a dipole antenna array mountainous terrain with a random rough surface in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a mountainous terrain using a surface object generated with a bi-cubic spline profile. The dipole elements are all thin wiressurface is then roughened based on the specified statistics. This wizard can be used to create either a mountain range with three peaks or a single-peak mountain.
PYTHON COMMAND(S): emag_dipole_arrayemag_mountain(len_lambdais_range,spacing_lambdaarea_size,nxheight,nyheight_diff,wire_rad_lambdaradius,spacing,elevation,res,rms_height,correl_len)
DIPOLE ARRAY MOUNTAINOUS TERRAIN WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | len_lambdais_range| real numericBoolean
| -
| 0.5 True | length of dipole normalized to free-space wavelength if true, creates a mountain range with three peaks, otherwise, creates a single peak
|-
! scope="row" | spacing_lambdaarea_size
| real numeric
| meter| 200| dimensions of the square terrain surface| -! scope="row" | 0.5 height| element real numeric| meter| 200| height of the mountain|-! scope="row" | height_diff| real numeric| meter| 40| difference between the heights of the center peak and the two lateral peaks in the case of a mountain range|-! scope="row" | radius| real numeric| meter| 50| radius of the bi-cubic spline surface profile|-! scope="row" | spacing normalized to free| real numeric| meter| 70| spacing between the center peak and the two lateral peaks in the case of a mountain range|-space wavelength ! scope="row" | elevation| real numeric| meter| 1| base elevation of whole terrain surface |-! scope="row" | res| real numeric| meter| 5| resolution of terrain surface |-! scope="row" | rms_height| real numeric| meter| 1| RMS height of the random rough surface |-! scope="row" | correl_len| real numeric| meter| 5| correlation length of the random rough surface |} <table><tr><td>[[Image:wiz_mountain.png|thumb|500px|Default mountainous terrain in EM.Terrano.]]</td></tr></table> == Office Building Wizard == ICON: [[File:office_icon.png]]  MENU: '''Tools → Propagation Wizards → Office Building''' MODULE(S): [[EM.Terrano]] FUNCTION: Creates a multi-story office building with penetrable walls in the project workspace NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates an office building with multiple floor and rows of rooms separated by hallways.   PYTHON COMMAND(S): emag_office_building(room_len,room_wid,room_height,hallway_width,nx,ny,nz,er,sig,wall_thickness)  OFFICE BUILDING WIZARD PARAMETERS{| border="0"|-| valign="top"||-{| class="wikitable"|-! scope="col"| Parameter Name! scope="col"| Value Type! scope="col"| Units! scope="col"| Default Value! scope="col"| Notes|-! scope="row" | room_len| real numeric| meter| 6| length of individual rooms|-! scope="row" | room_wid| real numeric| meter| 8| width of individual rooms|-! scope="row" | room_height| real numeric| meter| 4| height of individual rooms|-! scope="row" | hallway_wid| real numeric| meter| 2| width of interior hallways
|-
! scope="row" | nx
| -
| 5
| number of elements rooms along X
|-
! scope="row" | ny
| integer numeric
| -
| 1 3 | number of elements rooms along Y
|-
! scope="row" | wire_rad_lambdanz| integer numeric| -| 2 | number of floors (number of rooms along Z)|-! scope="row" | er
| real numeric
| -
| 04.002 4| relative permittivity of building walls| wire radius normalized to free-space wavelength ! scope="row" | sig| real numeric| S/m| 1e-3| conductivity of building walls|-! scope="row" | wall_thickness| real numeric| meter| 0.25| thickness of the individual walls
|}
<tr>
<td>
[[Image:wiz_dipole_arraywiz_office.png|thumb|500px|Default thin wire dipole array office building scene in EM.LiberaTerrano with its rooms in the freeze state.]]
</td>
</tr>
</table>
== Yagi-Uda Array Parabolic Reflector Wizard ==
ICON: [[File:yagi dish icon.png]]
MENU: '''Tools → Antenna Component Wizards → Yagi-Uda Dipole ArrayParabolic Reflector'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Illumina]], [[EM.Ferma]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a Yagi-Uda wire dipole array parabolic reflector in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: The dipole elements are all thin wiresaperture diameter of the reflector is determined based on the focal and axial lengths of the primitive parabola.
PYTHON COMMAND(S): emag_yagiemag_parabolic_reflector(excite_len_lambdafocal_len,reflect_len_lambda,reflect_spacing_lambda,direct_len_lambda,direct_spacing_lambda,n_direct,wire_rad_lambdaaxial_len)
YAGI PARABOLIC REFLECTOR WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | excite_len_lambdafocal_len
| real numeric
| -project units| 0.47 50| focal length of exciter dipole normalized to free-space wavelength the primitive parabola
|-
! scope="row" | reflect_len_lambdaaxial_len
| real numeric
| project units
| 70
| axial length of the primitive parabola
|}
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<table>
<tr>
<td>
[[Image:wiz_dish_tempo.png|thumb|360px|Default parabolic reflector in EM.Tempo.]]
</td>
</tr>
</table>
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== Particle Cloud Wizard ==
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ICON: [[File:cloud icon.png]]
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MENU: '''Tools → Component Wizards → Particle Cloud'''
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MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Illumina]], [[EM.Ferma]], [[EM.Libera]]
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FUNCTION: Creates the parameterized geometry of a random cloud of regular polygon particles contained in an ellipsoid region
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NOTES, SPECIAL CASES OR EXCEPTIONS: The aperture diameter of the reflector is determined based on the focal and axial lengths of the primitive parabola.
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PYTHON COMMAND(S):
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emag_particle_cloud(n_sides,side_length,cont_radius_x,cont_radius_y,cont_radius_z,n_elements)
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emag_particle_cloud_cad(n_sides,side_length,cont_radius_x,cont_radius_y,cont_radius_z,n_elements)
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PARTICLE CLOUD WIZARD PARAMETERS
{| border="0"
|-
| valign="top"|
|-
{| class="wikitable"
|-
! scope="col"| Parameter Name
! scope="col"| Value Type
! scope="col"| Units
! scope="col"| Default Value
! scope="col"| Notes
|-
! scope="row" | n_sides
| integer numeric
| -
| 0.5 4| length number of reflector dipole normalized to free-space wavelength sides of the regular polygon particle
|-
! scope="row" | reflect_spacingn_lambdaside_length
| real numeric
| -project units| 0.25 2| spacing between reflector and exciter dipoles normalized to free-space wavelength side length of the regular polygon particle
|-
! scope="row" | direct_len_lambdacont_radius_x
| real numeric
| -project units| 0.406 200| length radius of director dipoles normalized to free-space wavelength the ellipsoid container along X
|-
! scope="row" | direct_spacing_lambdacont_radius_y
| real numeric
| -project units| 0.34 200| spacing between director dipoles normalized to free-space wavelength radius of the ellipsoid container along Y
|-
! scope="row" | n_directcont_radius_z| real numeric| project units| 100| radius of the ellipsoid container along Z |-! scope="row" | n_elements
| integer numeric
| -
| 5 100| total number of director dipole elements along X |-! scope="row" | wire_rad_lambda| real numeric| -| 0.003 | wire radius normalized to free-space wavelength particles
|}
<tr>
<td>
[[Image:wiz_yagiwiz_cloud_tempo.png|thumb|500px|Default thin wire Yagi-Uda dipole array particle cloud in EM.LiberaTempo with the ellipsoid container in the freeze state.]]
</td>
</tr>
</table>
== Printed Dipole Plateau Terrain Wizard ==
ICON: [[File:print_dpl iconplateau_icon.png]]
MENU: '''Tools → Antenna Propagation Wizards → Printed Dipole AntennaPlateau Terrain'''
MODULE(S): [[EM.Tempo]], [[EM.PicassoTerrano]]
FUNCTION: Creates the parameterized geometry of a printed dipole antenna on plateau terrain with a dielectric substrate random rough surface in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]], the printed dipole consists of two PEC strips fed by This wizard creates a lumped source on plateau terrain using a short joining linesurface object generated with a bi-sigmoid profile. In [[EM.Picasso]], the printed dipole The surface is a single PEC strip with a gap source then roughened based on itthe specified statistics.
PYTHON COMMAND(S): emag_plateau(area_size,height,slope,elevation,res,rms_height,correl_len)
emag_printed_dipole_tempo(h,er,wid,sub_size,has_ground)
emag_printed_dipole_picasso(h,er,wid,has_ground)Â Â PRINTED DIPOLE PLATEAU TERRAIN WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | harea_size
| real numeric
| meter
| 0.0015200| substrate thickness (height) dimensions of the square terrain surface
|-
! scope="row" | erheight
| real numeric
| -meter| 2.2 10| substrate relative permittivity height of the hill
|-
! scope="row" | widslope
| real numeric
| meter
| 0.0051| strip width slope of the bi-sigmoid surface profile
|-
! scope="row" | sub_sizeelevation
| real numeric
| meter
| 0.155| substrate dimensions along X and Y (only in [[EM.Tempo]])base elevation of whole terrain surface
|-
! scope="row" | has_groundres| Booleanreal numeric| meter| 10| resolution of terrain surface | -! scope="row" | Truerms_height| Places a PEC ground plane real numeric| meter| 0.5| RMS height of the same size as random rough surface |-! scope="row" | correl_len| real numeric| meter| 10| correlation length of the dielectric substrate random rough surface
|}
<tr>
<td>
[[Image:wiz_print_dpl_tempowiz_plateau.png|thumb|500px|Default printed dipole antenna plateau terrain in EM.Tempo.]]</td></tr><tr><td>[[Image:wiz_print_dpl_picasso.png|thumb|500px|Default printed dipole antenna in EM.PicassoTerrano.]]
</td>
</tr>
</table>
== Probe-Fed Patch Printed Dipole Wizard ==
ICON: [[File:probe_patch_iconprint_dpl icon.png]]
MENU: '''Tools → Antenna Wizards → Probe-Fed Patch Printed Dipole Antenna'''
MODULE(S): [[EM.Tempo]], [[EM.Picasso]]
FUNCTION: Creates the parameterized geometry of a probe-fed rectangular patch printed dipole antenna on a dielectric substrate in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]], the patch antenna is printed dipole consists of two PEC strips fed by a lumped source on a short vertical PEC joining line. In [[EM.Picasso]], the patch antenna printed dipole is fed by a probe single PEC strip with a gap source on a short vertical PEC via. In both modules, the dimensions of the square patch are set equal to 0.47 times the effective dielectric wavelength, which can be changedit.
PYTHON COMMAND(S):
emag_patch_tempoemag_printed_dipole_tempo(h,er,feed_ratiowid,sub_size,has_ground)
emag_patch_picassoemag_printed_dipole_picasso(h,er,feed_ratiowid,feed_radhas_ground)
PATCH PRINTED DIPOLE WIZARD PARAMETERS
{| border="0"
|-
| substrate relative permittivity
|-
! scope="row" | feed_ratio| real numeric| -| 0.4| ratio of location of probe to half patch length xf/(a/2) |-! scope="row" | feed_radwid
| real numeric
| meter
| 0.005
| radius of probe via strip width
|-
! scope="row" | sub_size
| 0.15
| substrate dimensions along X and Y (only in [[EM.Tempo]])
|-
! scope="row" | has_ground
| Boolean
| -
| True
| Places a PEC ground plane of the same size as the dielectric substrate
|}
<tr>
<td>
[[Image:wiz_patch_tempowiz_print_dpl_tempo.png|thumb|500px|Default probe-fed patch printed dipole antenna in EM.Tempo.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_patch_picassowiz_print_dpl_picasso.png|thumb|500px|Default probe-fed patch printed dipole antenna in EM.Picasso.]]
</td>
</tr>
</table>
== MicrostripProbe-Fed Patch Wizard ==
ICON: [[File:us_patch_iconprobe_patch_icon.png]]
MENU: '''Tools → Antenna Wizards → MicrostripProbe-Fed Patch Antenna'''
MODULE(S): [[EM.Tempo]], [[EM.Picasso]]
FUNCTION: Creates the parameterized geometry of a microstripprobe-fed rectangular patch antenna in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: The wizard asks you whether you want a microstrip-fed patch antenna with a recessed feed or one with a direct microstrip line junction. In [[EM.Tempo]], the feed line patch antenna is excited fed by a microstrip portlumped source on a short vertical PEC line. In [[EM.Picasso]], the feed line has patch antenna is fed by a scattering wave portprobe source on a short vertical PEC via. The total In both modules, the dimensions of the square patch are set equal to 0.5 47 times the effective dielectric wavelength, which can be changed.
PYTHON COMMAND(S):
emag_microstrip_fed_patch_tempoemag_patch_tempo(is_recess,h,er,z0,feed_len,recess_dep,recess_wid,sub_lenfeed_ratio,sub_widsub_size)
emag_microstrip_fed_patch_picassoemag_patch_picasso(is_recess,h,er,z0,feed_len,recess_depfeed_ratio,recess_widfeed_rad)
MICROSTRIP-FED PATCH WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Default Value
! scope="col"| Notes
|-
! scope="row" | is_recess
| Boolean
| -
| True
| Creates a recessed feed vs. a direct microstrip line junction to the patch
|-
! scope="row" | h
| substrate relative permittivity
|-
! scope="row" | z0feed_ratio
| real numeric
| Ohms-| 50 0.4| characteristic impedance ratio of the microstrip feed location of probe to half patch length xf/(a/2)
|-
! scope="row" | feed_len| real numeric| meter| 0.075| length of the microstrip feed line |-! scope="row" | recess_dep| real numeric| meter| 0.015| depth of the feed recess |-! scope="row" | recess_widfeed_rad
| real numeric
| meter
| 0.005
| width radius of the recess gaps probe via
|-
! scope="row" | sub_lensub_size
| real numeric
| meter
| 0.315| substrate dimension dimensions along X (only in [[EM.Tempo]])|-! scope="row" | sub_wid| real numeric| meter| 0.3| substrate dimension along and Y (only in [[EM.Tempo]])
|}
<tr>
<td>
[[Image:wiz_us_patch_tempowiz_patch_tempo.png|thumb|500px|Default microstripprobe-fed patch antenna in EM.Tempo.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_us_patch_picassowiz_patch_picasso.png|thumb|500px|Default microstripprobe-fed patch antenna in EM.Picasso.]]</td></tr><tr><td>[[Image:wiz_us_patch_recess_tempo.png|thumb|500px|Default microstrip-fed patch antenna with a recessed feed in EM.Tempo.]]</td></tr><tr><td>[[Image:wiz_us_patch_recess_picasso.png|thumb|500px|Default microstrip-fed patch antenna with a recessed feed in EM.Picasso.]]
</td>
</tr>
</table>
== Slot-Coupled Patch Random City Wizard ==
ICON: [[File:slot_patch_iconrnd_city_icon.png]]
MENU: '''Tools → Antenna Propagation Wizards → Slot-Coupled Patch AntennaRandom City'''
MODULE(S): [[EM.Tempo]], [[EM.PicassoTerrano]]
FUNCTION: Creates the parameterized geometry of a slot-coupled rectangular patch antenna set of randomly located and randomly oriented buildings with random dimensions and impenetrable walls in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a substrate realistic urban propagation scene with two dielectric layers, which are separated by randomly located buildings in a PEC ground plane hosting a coupling slotsquare area of specified size. The upper layer hosts a rectangular patch antennaIt can be used in two different ways. The bottom layer hosts a microstrip feed line with an open stubIn the fully random mode, which is extended past all the slot location. The total dimensions of the square patch generated buildings are set equal to 0assigned and always retain random parameter values.47 times Every time you open the Variables Dialog or open the effective dielectric wavelengthsame project, which can be changedall the random variables get updated values. The length of In the open stub beyond semi-random mode, the slot location is set equal to a quarter guide wavelengthbuildings are initially generated based on random parameter values, which can be changed, toobut these value are then fixed and locked for good.
PYTHON COMMAND(S): emag_random_city(city_size,n_buildings,rotate_bldg,semi_random,building_base_min,building_base_max,building_height_min,building_height_max,er,sig)
emag_slot_coupled_patch_tempo(h_patch,er_patch,h_feed,er_feed,slot_len,slot_wid,z0,feed_len,sub_len,sub_wid)
emag_slot_coupled_patch_picasso(h_patch,er_patch,h_feed,er_feed,slot_len,slot_wid,z0,feed_len)Â Â SLOT-COUPLED PATCH RANDOM CITY WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | h_patchcity_size
| real numeric
| meter
| 0.0015250| thickness (height) total dimensions of the top substrate layer square city area
|-
! scope="row" | er_patchn_buildings| real integer numeric
| -
| 2.2 25 | relative permittivity total number of the top substrate layerbuildings
|-
! scope="row" | h_feedrotate_bldg| real numericBoolean| meter-| 0.0015False| thickness (height) of sets the bottom substrate layer rotation angles of each building as random variables
|-
! scope="row" | er_feedsemi_random| real numericBoolean
| -
| 2.2 True| relative permittivity if false, the the locations, orientations and extents of the bottom substrate layerbuildings change randomly all the time
|-
! scope="row" | slot_lenbuilding_base_min
| real numeric
| meter
| 0.0210| length minimum dimension of the coupling slot base of the individual buildings
|-
! scope="row" | slot_widbuilding_base_max
| real numeric
| meter
| 0.002520| width maximum dimension of the coupling slot base of the individual buildings
|-
! scope="row" | z0building_height_min
| real numeric
| Ohmsmeter| 50 5| characteristic impedance minimum height of the microstrip feed individual buildings
|-
! scope="row" | feed_lenbuilding_height_max
| real numeric
| meter
| 0.120| length maximum height of the microstrip feed line individual buildings
|-
! scope="row" | sub_lener
| real numeric
| meter-| 04.34| substrate dimension along X (only in [[EM.Tempo]])relative permittivity of building walls
|-
! scope="row" | sub_widsig
| real numeric
| meterS/m| 0.1e-3| substrate dimension along Y (only in [[EM.Tempo]])conductivity of building walls
|}
<tr>
<td>
[[Image:wiz_slot_patch_tempowiz_random_city1.png|thumb|500px|Default slot-coupled patch antenna random city propagation scene in EM.Tempo with the patch, middle ground and substrate layers in the freeze stateTerrano.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_slot_patch_picassowiz_random_city1_rot.png|thumb|500px|Default slot-coupled patch antenna random city propagation scene in EM.Picasso Terrano with the patch in the freeze staterandom building orientations.]]
</td>
</tr>
</table>
== Linear Slot Rectangular Waveguide Wizard ==
ICON: [[File:slot_iconwg1p icon.png]]
MENU: '''Tools → Antenna Transmission Line Wizards → Linear SlotRectangular Waveguide'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Illumina]], [[EM.Ferma]], [[EM.LiberaTempo]]
FUNCTION: Creates the parameterized geometry of a narrow rectangular slot in a ground planewaveguide segment slightly above the cutoff at the center frequency of the project
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard simply creates a linear slot one-port open-ended rectangular waveguide segment in a ground plane using Boolean subtraction[[EM.Tempo]]. The width of the waveguide is set slightly larger than half its cutoff wavelength for the dominant TE10 mode. The height is set equal to half its width. Both the width and height can be replaced by arbitrary numeric values.
PYTHON COMMAND(S): emag_linear_slotemag_rect_waveguide(slot_lenwg_len,slot_wid,metal_sizeport_offset)
LINEAR SLOT WAVEGUIDE WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | slot_lenwg_len
| real numeric
| project unitsmeters | 1001| length of the slot waveguide segment
|-
! scope="row" | slot_widport_offset
| real numeric
| project unitsmeters | 100.075 | width distance between port plane and the first open end of the slot waveguide |} <table><tr><td>[[Image:wiz_wg_tempo.png|thumb|500px|Default rectangular waveguide segment with a shorted end wall in EM.Tempo.]]</td></tr></table> == Sierpinski Wizard == ICON: [[File:sierpin icon.png]]  MENU: '''Tools → Component Wizards → Sierpinski Strip''' MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Illumina]], [[EM.Ferma]], [[EM.Picasso]], [[EM.Libera]]  FUNCTION: Creates the geometry of a Sierpinski triangle fractal in the project workspace NOTES, SPECIAL CASES OR EXCEPTIONS: A dialog asks you to enter values for the key size and number of fractal levels. The wizard creates the Sierpinski triangle as a large set of smaller triangles, which cannot be modified using variables afterwards. You may want to group the set of all the triangles as a single composite object.   PYTHON COMMAND(S): emag_sierpinski(key_size,levels)  SIERPINSKI WIZARD PARAMETERS{| border="0"
|-
| valign="top"||-{| class="wikitable"|-! scope="col"| Parameter Name! scope="col"| Value Type! scope="col"| Units! scope="col"| Default Value! scope="col"| Notes|-! scope="row" | metal_sizekey_size
| real numeric
| project units
| 200100| dimensions side length of the square metal groundlargest (outermost) triangle |-! scope="row" | levels| integer numeric| -| 3| number of fractal levels
|}
<tr>
<td>
[[Image:wiz_slot_cadwiz_sierpin_tempo.png|thumb|500px|Default linear slot Sierpinski triangle strip in CubeCADEM.Tempo.]]
</td>
</tr>
</table>
== Slot Antenna Array Wizard ==
ICON: [[File:slot_iconslot_array_icon.png]]
MENU: '''Tools → Antenna Wizards → Linear Slot AntennaArray'''
MODULE(S): [[EM.Tempo]], [[EM.Picasso]]
FUNCTION: Creates the parameterized geometry of a slot antenna array in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]], the wizard creates a an array of slot antenna antennas excited by a lumped source sources on a short line lines across the slotslots. In [[EM.Picasso]], the wizard creates a slot antenna array on a slot trace fed by a magnetic gap (current) sourcesources. The length of the each slot is set equal to a half the effective wavelength, which can be changed.
PYTHON COMMAND(S):
emag_slot_tempoemag_slot_array_tempo(h,er,slot_wid,sub_size,feed_offset,nx,ny,spacing_x_lambda,spacing_y_lambda)
emag_slot_picassoemag_slot_array_picasso(h,er,slot_wid,feed_offset,nx,ny,spacing_x_lambda,spacing_y_lambda)
SLOT ANTENNA ARRAY WIZARD PARAMETERS
{| border="0"
|-
| meter
| 0.2
| dimensions of the square substrate & ground (only in [[EM|-! scope="row" | nx| integer numeric| -| 2 | number of elements along X |-! scope="row" | ny| integer numeric| -| 2 | number of elements along Y |-! scope="row" | spacing_x_lambda| real numeric| -| 0.Tempo]])5| element spacing along X normalized to free-space wavelength|-! scope="row" | spacing_y_lambda| real numeric| -| 0.5| element spacing along Y normalized to free-space wavelength
|}
<table>
<tr>
<td>
[[Image:wiz_slot_tempowiz_slot_array_tempo.png|thumb|500px|Default slot antenna array in EM.Tempo.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_slot_picassowiz_slot_array_picasso.png|thumb|500px|Default slot antenna array in EM.Picasso.]]
</td>
</tr>
</table>
== Linear Slot Array Antenna Wizard ==
ICON: [[File:slot_array_iconslot_icon.png]]
MENU: '''Tools → Antenna Wizards → Linear Slot ArrayAntenna'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Illumina]], [[EM.FermaTempo]], [[EM.LiberaPicasso]]
FUNCTION: Creates the parameterized geometry of an array of narrow rectangular slots in a ground planeslot antenna in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This In [[EM.Tempo]], the wizard simply creates an array a slot antenna excited by a lumped source on a short line across the slot. In [[EM.Picasso]], the wizard creates a slot antenna on a slot trace fed by a magnetic gap (current) source. The length of linear slots in the slot is set equal to a ground plane using Boolean subtractionhalf the effective wavelength, which can be changed.
PYTHON COMMAND(S): emag_linear_slot_array(slot_len,slot_wid,nx,ny,spacing_x,spacing_y)
emag_slot_tempo(h,er,slot_wid,sub_size,feed_offset)
LINEAR emag_slot_picasso(h,er,slot_wid,feed_offset)Â Â SLOT ARRAY ANTENNA WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | slot_lenh
| real numeric
| project unitsmeter| 1000.0015| length of the slot substrate thickness (height) |-! scope="row" | er| real numeric| -| 2.2 | substrate relative permittivity
|-
! scope="row" | slot_wid
| real numeric
| project unitsmeter| 100.005
| width of the slot
|-
! scope="row" | nx| integer numeric| -| 2 | number of elements along X |-! scope="row" | ny| integer numeric| -| 2 | number of elements along Y |-! scope="row" | spacing_xfeed_offset
| real numeric
| -meter| 1500.0| element spacing along Xdistance of feed from center of the slot - can be positive or negative
|-
! scope="row" | spacing_ysub_size
| real numeric
| -meter| 1500.2| element spacing along Ydimensions of the square substrate & ground (only in [[EM.Tempo]])
|}
<tr>
<td>
[[Image:wiz_slot_array_cadwiz_slot_tempo.png|thumb|500px|Default linear slot array antenna in CubeCADEM.Tempo.]]</td></tr><tr><td>[[Image:wiz_slot_picasso.png|thumb|500px|Default slot antenna in EM.Picasso.]]
</td>
</tr>
</table>
== Slot Antenna Array -Coupled Patch Wizard ==
ICON: [[File:slot_array_iconslot_patch_icon.png]]
MENU: '''Tools → Antenna Wizards → Slot -Coupled Patch Antenna Array'''
MODULE(S): [[EM.Tempo]], [[EM.Picasso]]
FUNCTION: Creates the parameterized geometry of a slot -coupled rectangular patch antenna array in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]], the This wizard creates an array of slot antennas excited a substrate with two dielectric layers, which are separated by lumped sources on short lines across the slotsa PEC ground plane hosting a coupling slot. In [[EMThe upper layer hosts a rectangular patch antenna.Picasso]]The bottom layer hosts a microstrip feed line with an open stub, which is extended past the wizard creates a slot antenna array on a slot trace fed by a magnetic gap (current) sourceslocation. The total dimensions of the square patch are set equal to 0.47 times the effective dielectric wavelength, which can be changed. The length of each the open stub beyond the slot location is set equal to a half the effective quarter guide wavelength, which can be changed, too.
PYTHON COMMAND(S):
emag_slot_array_tempoemag_slot_coupled_patch_tempo(hh_patch,erer_patch,slot_widh_feed,feed_offseter_feed,slot_len,slot_wid,nxz0,nyfeed_len,spacing_x_lambdasub_len,spacing_y_lambdasub_wid)
emag_slot_array_picassoemag_slot_coupled_patch_picasso(hh_patch,erer_patch,slot_widh_feed,feed_offseter_feed,nxslot_len,nyslot_wid,spacing_x_lambdaz0,spacing_y_lambdafeed_len)
SLOT ANTENNA ARRAY -COUPLED PATCH WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | hh_patch
| real numeric
| meter
| 0.0015
| substrate thickness (height) of the top substrate layer
|-
! scope="row" | erer_patch
| real numeric
| -
| 2.2
| substrate relative permittivity of the top substrate layer
|-
! scope="row" | slot_widh_feed
| real numeric
| meter
| 0.0050015| width thickness (height) of the slot bottom substrate layer
|-
! scope="row" | feed_offseter_feed| real numeric| -| 2.2 | relative permittivity of the bottom substrate layer|-! scope="row" | slot_len
| real numeric
| meter
| 0.002| distance of feed from center length of the coupling slot - can be positive or negative
|-
! scope="row" | sub_sizeslot_wid
| real numeric
| meter
| 0.20025| dimensions width of the square substrate & groundcoupling slot
|-
! scope="row" | nxz0| integer real numeric| -Ohms| 2 50 | number characteristic impedance of elements along X the microstrip feed
|-
! scope="row" | nyfeed_len| integer real numeric| -meter| 2 0.1| number length of elements along Y the microstrip feed line
|-
! scope="row" | spacing_x_lambdasub_len
| real numeric
| -meter| 0.53| element spacing substrate dimension along X normalized to free-space wavelength(only in [[EM.Tempo]])
|-
! scope="row" | spacing_y_lambdasub_wid
| real numeric
| -meter| 0.53| element spacing substrate dimension along Y normalized to free-space wavelength(only in [[EM.Tempo]])
|}
<table>
<tr>
<td>
[[Image:wiz_slot_array_tempowiz_slot_patch_tempo.png|thumb|500px|Default slot -coupled patch antenna array in EM.Tempowith the patch, middle ground and substrate layers in the freeze state.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_slot_array_picassowiz_slot_patch_picasso.png|thumb|500px|Default slot -coupled patch antenna array in EM.Picassowith the patch in the freeze state.]]
</td>
</tr>
</table>
== Cross Slot Solenoid Wizard ==
ICON: [[File:cross_iconsolenoid icon.png]]
MENU: '''Tools → Antenna Component Wizards → Cross SlotSolenoid'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.IlluminaTempo]], [[EM.Ferma]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a narrow solenoid with a generalized super-quadratic cross slot section in a ground planethe project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This In [[EM.Ferma]], this wizard simply creates a cross slot in turns the solenoid into a ground plane using Boolean subtractionwire current source.
PYTHON COMMAND(S): emag_cross_slot(slot_len,slot_wid,metal_size)
emag_solenoid(major_rad,minor_rad,height,turns,order,step)
LINEAR SLOT emag_solenoid_ferma(major_rad,minor_rad,height,turns,order,step,current,wire_rad)Â Â SOLENOID WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | slot_lenmajor_rad
| real numeric
| project units
| 1002 | total length major radius of each slot armthe super-quadratic cross section
|-
! scope="row" | slot_widminor_rad
| real numeric
| project units
| 102 | total width minor radius of each slot arm the super-quadratic cross section
|-
! scope="row" | metal_sizeheight
| real numeric
| project units| 20010 | dimensions total height of the square metal groundsolenoid |-! scope="row" | turns| integer numeric| - | 10 | total number of turns|-! scope="row" | order| integer numeric| - | 2 | order of the super-quadratic curve, N = 2 produces an ellipse|-! scope="row" | step| real numeric| - | 0.005 | increment in the interval [0, 2*pi] - determines the resolution of the curve |-! scope="row" | current| real numeric| Amp | 1| total current flowing through the solenoid (only in [[EM.Ferma]])|-! scope="row" | wire_rad| real numeric| project units | 0.0005 | radius of the solenoid wire (only in [[EM.Ferma]])
|}
<tr>
<td>
[[Image:wiz_cross_cadwiz_solenoid_cad.png|thumb|500px360px|Default cross slot solenoid in CubeCAD.]]</td></tr><tr><td>[[Image:wiz_solenoid_ferma.png|thumb|360px|Default solenoid in EM.Ferma.]]
</td>
</tr>
</table>
== Cross Slot Antenna Stripline Wizard ==
ICON: [[File:cross_iconus1p icon.png]]
MENU: '''Tools → Antenna Transmission Line Wizards → Cross Slot AntennaStripline Line'''
MODULE(S): [[EM.Tempo]], [[EM.Picasso]], [[EM.Ferma]]
FUNCTION: Creates the parameterized geometry of a cross slot antenna stripline segment of a specified characteristic impedance on a conductor-backed single-layer dielectric substrate in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: In [[EM.Tempo]] and [[EM.Picasso]], the this wizard creates a cross slot antenna on a dielectric substrateone-port open-ended stripline transmission line segment. In [[EM.PicassoFerma]], it sets up a 2D solution plane for quasi-static analysis of the wizard creates a cross slot antenna on a slot tracestripline transmission line. The total length width of each slot the stripline is set equal to a half determined based on the effective wavelength, which can specified characteristic impedance. It may be changed. This wizard does not provide replaced by a default excitation source in either modulenumeric value instead.
PYTHON COMMAND(S):
emag_slot_tempoemag_stripline_tempo(hht,erert,slot_widhb,sub_sizeerb,feed_wid,cetner_len,sub_len,sub_wid)
emag_slot_picassoemag_stripline_picasso(hht,erert,slot_widhb,erb,feed_wid,center_len)
emag_stripline_ferma(ht,ert,hb,erb,strip_wid,box_multiplier)
CROSS SLOT ANTENNA [[EM.Tempo|EM.TEMPO]] STRIPLINE WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | hht
| real numeric
| metermeters | 0.0015| top substrate thickness (height(thickness)
|-
! scope="row" | erert
| real numeric
| -
| 2.2
| top substrate relative permittivity
|-
! scope="row" | slot_widhb
| real numeric
| metermeters | 0.0050015 | width of the slot bottom substrate height (thickness)
|-
! scope="row" | sub_sizeerb
| real numeric
| meter- | 02.2| dimensions bottom substrate relative permittivity |-! scope="row" | feed_wid| real numeric| meters| 0.002 | width of the square feed strip segment|-! scope="row" | center_wid| real numeric| meters| feed_wid| width of center strip segment|-! scope="row" | center_len| real numeric| meters | 0.03 | length of center line segment |-! scope="row" | sub_len| real numeric| meters | 0.1 | length of substrate|-! scope="row" | sub_wid| real numeric| meters | 0.05 | width of substrate|}Â [[EM.Picasso|EM.PICASSO]] STRIPLINE WIZARD PARAMETERS{| border="0"|-| valign="top"||-{| class="wikitable"|-! scope="col"| Parameter Name! scope="col"| Value Type! scope="col"| Units! scope="col"| Default Value! scope="col"| Notes|-! scope="row" | ht| real numeric| meters | 0.0015 | top substrate & ground height (only in thickness) |-! scope="row" | ert | real numeric| - | 2.2 | top substrate relative permittivity |-! scope="row" | hb| real numeric| meters | 0.0015 | bottom substrate height (thickness) |-! scope="row" | erb | real numeric| - | 2.2 | bottom substrate relative permittivity |-! scope="row" | feed_wid| real numeric| meters| center_width | width of feed strip segment|-! scope="row" | center_wid| real numeric| meters| feed_wid | width of center strip segment|-! scope="row" | center_len| real numeric| meters | 0.03 | length of center line segment |-! scope="row" | feed_len| real numeric| meters | 0.5 * center_len| length of feed line segment |}Â [[EM.TempoFerma|EM.FERMA]]STRIPLINE WIZARD PARAMETERS{| border="0"|-| valign="top"||-{| class="wikitable"|-! scope="col"| Parameter Name! scope="col"| Value Type! scope="col"| Units! scope="col"| Default Value! scope="col"| Notes|-! scope="row" | ht| real numeric| meters | 0.0015 | top substrate height (thickness)|-! scope="row" | ert | real numeric| - | 2.2 | top substrate relative permittivity |-! scope="row" | hb| real numeric| meters | 0.0015 | bottom substrate height (thickness) |-! scope="row" | erb | real numeric| - | 2.2 | bottom substrate relative permittivity |-! scope="row" | strip_wid| real numeric| meters| 0.002 | strip width |-! scope="row" | box_multiplier| real numeric| - | 10 | ratio of box width to strip width
|}
<table>
<tr>
<td>
[[Image:wiz_cross_tempoWiz strpln tempo.png|thumb|500px|Default cross slot antenna stripline line segment in EM.Tempo.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_cross_picassoWiz strpln picasso.png|thumb|500px|Default cross slot antenna stripline line segment in EM.Picasso.]]</td></tr><tr><td>[[Image:Wiz strpln ferma.png|thumb|500px|Default 2D stripline line in EM.Ferma.]]
</td>
</tr>
</table>
== Horn Antenna Trihedral Reflector Wizard ==
ICON: [[File:horn_icontrihed icon.png]]
MENU: '''Tools → Antenna Component Wizards → Horn AntennaTrihedral Reflector'''
MODULE(S): [[Building_Geometrical_Constructions_in_CubeCAD | CubeCAD]], [[EM.Tempo]], [[EM.Illumina]], [[EM.Ferma]], [[EM.Libera]]
FUNCTION: Creates the parameterized geometry of a pyramidal horn antenna Trihedral corner reflector in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a pyramidal horn antenna fed by a rectangular waveguide with a TE10 modal excitation. The larger dimension aperture diameter of the feeding waveguide reflector is set slightly larger than half its cutoff wavelength for the dominant TE10 mode. The aspect ratio of the waveguide's cross section is 2:1. Its length is set to half the free-space wavelength. All of these dimensions can be replaced by arbitrary numeric values. The horn aperture dimensions and its overall length are calculated determined based on the specified antenna gain. All focal and axial lengths of these dimensions can be changed, toothe primitive parabola.
PYTHON COMMAND(S): emag_hornemag_trihedral_reflector(gain_dBside)
HORN ANTENNA TRIHEDRAL REFLECTOR WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | gain_dBside
| real numeric
| -project units| 15100| gain of the horn antenna square wall dimensions
|}
<tr>
<td>
[[Image:wiz_hornwiz_trihed_tempo.png|thumb|500px360px|Default horn antenna trihedral reflector in EM.Tempo.]]
</td>
</tr>
</table>
== Horn Antenna Array Two-Port Coaxial Wizard ==
ICON: [[File:horn_array_iconcoax2p icon.png]]
MENU: '''Tools → Antenna Transmission Line Wizards → Horn Antenna ArrayTwo-Port Coaxial Line'''
MODULE(S): [[EM.Tempo]]
FUNCTION: Creates the parameterized geometry of a pyramidal horn antenna array two-port coaxial line segment of a specified characteristic impedance with a dielectric core in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates an array of pyramidal horn antennas fed by rectangular waveguides with a TE10 modal excitation. The larger dimension radius of each feeding waveguide is set slightly larger than half its cutoff wavelength for the dominant TE10 mode. The aspect ratio of each waveguide's cross section outer conductor is 2:1. Its length is set to half determined based on the free-space wavelengthspecified characteristic impedance. All of these dimensions can It may be replaced by arbitrary a numeric values. The horn aperture dimensions and its overall length are calculated based on the specified antenna gain. All of these dimensions can be changed, toovalue instead.
PYTHON COMMAND(S): emag_horn_arrayemag_coax_2port_tempo(gain_dBer,nxz0,nyr_inner,spacing_x_lambda,spacing_y_lambdalen)
CROSS SLOT ANTENNA TWO-PORT COAXIAL WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | gain_dBer
| real numeric
| -| 152.2 | gain relative permittivity of each individual horn elementthe dielectric core
|-
! scope="row" | nxz0| integer real numeric| -Ohms | 2 50 | number of elements along X characteristic impedance
|-
! scope="row" | ny| integer numeric| -| 2 | number of elements along Y |-! scope="row" | spacing_x_lambdar_inner
| real numeric
| -meters | 30.001 | element spacing along X normalized to free-space wavelengthradius of inner conductor
|-
! scope="row" | spacing_y_lambdalen
| real numeric
| -meters | 30.5 | element spacing along Y normalized to free-space wavelengthlength of the line segment
|}
<tr>
<td>
[[Image:wiz_horn_arraywiz_coax2p_tempo.png|thumb|500px|Default horn antenna array two-port coaxial line segment in EM.Tempo.]]
</td>
</tr>
</table>
== Random City Two-Port Coplanar Waveguide (CPW) Wizard ==
ICON: [[File:rnd_city_iconcpw2p icon.png]]
MENU: '''Tools → Propagation Transmission Line Wizards → Random CityTwo-Port Coplanar Waveguide'''
MODULE(S): [[EM.TerranoTempo]], [[EM.Picasso]]
FUNCTION: Creates a set the parameterized geometry of randomly located and randomly oriented buildings with random dimensions and impenetrable walls a two-port coplanar waveguide segment on a single-layer dielectric substrate in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a realistic urban propagation scene with randomly located buildings in a square area of specified size. It can be used in two different ways. In the fully random mode, all the generated buildings are assigned and always retain random parameter values[[EM. Every time you open the Variables Dialog or open the same projectTempo]], all the random variables get updated values. In the semi-random mode, the buildings two ports are initially generated based on random parameter values, but these value are then fixed and locked for good. By default, a half-wave vertical dipole transmitter is placed at the center of the scene and a grid two edges of isotropic receivers cover the entire propagation scenesubstrate.
PYTHON COMMAND(S): emag_random_city(city_size,n_buildings,add_TxRx,rotate_bldg,semi_random,building_base_min,building_base_max,building_height_min,building_height_max,er,sig,tx_h,rx_h,rx_spacing)
emag_cpw_2port_tempo(h,er,center_wid,slot_wid,center_len,sub_len,sub_wid,draw_substrate)
RANDOM CITY emag_cpw_2port_picasso(h,er,center_wid,slot_wid,center_len)Â Â [[EM.Tempo|EM.TEMPO]] TWO-PORT CPW WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | city_sizeh
| real numeric
| metermeters | 2500.0015 | total dimensions of the square city areasubstrate height (thickness)
|-
! scope="row" | n_buildingser | integer real numeric| -| 25 2.2 | total number of buildingssubstrate relative permittivity
|-
! scope="row" | add_TxRxcenter_wid| Booleanreal numeric| -meters | True 0.002 | adds a default transmitter at width of the origin of coordinates and a grid of receivers center strip
|-
! scope="row" | rotate_bldgslot_wid| Booleanreal numeric| -meters | False0.002 | sets the rotation angles width of each building as random variables the slots
|-
! scope="row" | semi_random| Boolean| -| False| if true, the buildings are initially generated via random variables, but their parameters are locked afterwards |-! scope="row" | building_base_mincenter_len
| real numeric
| metermeters | 100.05 | minimum dimension length of the base of the individual buildingscenter line segment
|-
! scope="row" | building_base_maxsub_len
| real numeric
| metermeters | 200.1 | maximum dimension length of the base of the individual buildingssubstrate
|-
! scope="row" | building_height_minsub_wid
| real numeric
| metermeters | 50.05 | minimum height width of the individual buildingssubstrate
|-
! scope="row" | building_height_maxdraw_substrate| Boolean| -| True | Adds substrate & ground plane|}Â [[EM.Picasso|EM.PICASSO]] TWO-PORT CPW WIZARD PARAMETERS{| border="0"|-| valign="top"||-{| class="wikitable"|-! scope="col"| Parameter Name! scope="col"| Value Type! scope="col"| Units! scope="col"| Default Value! scope="col"| Notes|-! scope="row" | h
| real numeric
| metermeters | 200.0015 | maximum substrate height of the individual buildings(thickness)
|-
! scope="row" | er
| real numeric
| -| 42.42 | substrate relative permittivity of building walls
|-
! scope="row" | sigcenter_wid
| real numeric
| S/mmeters | 1e-30.002 | conductivity width of building wallsthe center strip
|-
! scope="row" | tx_hslot_wid
| real numeric
| metermeters | 100.002 | height width of the default transmitterslots
|-
! scope="row" | rx_hcenter_len
| real numeric
| metermeters | 1- | height length of the default receiverscenter line segment
|-
! scope="row" | rx_spacingfeed_len
| real numeric
| metermeters | 0.5* center_len | spacing among the individual receiverslength of feed line segment
|}
<tr>
<td>
[[Image:wiz_random_citywiz_cpw2p_tempo.png|thumb|500px|Default random city propagation scene two-port coplanar waveguide segment in EM.TerranoTempo.]]
</td>
</tr>
<tr>
<td>
[[Image:wiz_random_city_rotwiz_cpw2p_picasso.png|thumb|500px|Default random city propagation scene two-port coplanar waveguide segment in EM.Terrano with random building orientationsPicasso.]]
</td>
</tr>
</table>
== Office Building Two-Port Microstrip Wizard ==
ICON: [[File:office_iconus2p icon.png]]
MENU: '''Tools → Propagation Transmission Line Wizards → Office BuildingTwo-Port Microstrip Line'''
MODULE(S): [[EM.TerranoTempo]], [[EM.Picasso]]
FUNCTION: Creates the parameterized geometry of a multitwo-story office building with penetrable walls port microstrip line segment of a specified characteristic impedance on a conductor-backed single-layer dielectric substrate in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates an office building with multiple floor and rows In [[EM.Tempo]], the two ports are placed at the two edges of rooms separated the substrate. The width of the microstrip lines is determined based on the specified characteristic impedance. It may be replaced by hallwaysa numeric value instead.
PYTHON COMMAND(S): emag_office_building(room_len,room_wid,room_height,hallway_width,nx,ny,nz,er,sig,wall_thickness)
emag_microstrip_2port_tempo(h,er,z0,cetner_len,sub_len,sub_wid,draw_substrate)
OFFICE BUILDING emag_microstrip_2port_picasso(h,er,z0,center_len,feed_len)Â Â [[EM.Tempo|EM.TEMPO]] TWO-PORT MICROSTRIP WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | room_lenh
| real numeric
| metermeters | 60.0015 | length of individual roomssubstrate height (thickness)
|-
! scope="row" | room_wider
| real numeric
| meter- | 82.2 | width of individual roomssubstrate relative permittivity
|-
! scope="row" | room_heightz0
| real numeric
| meterOhms | 450 | height of individual roomscharacteristic impedance
|-
! scope="row" | hallway_widcenter_len
| real numeric
| metermeters | 20.05 | width length of interior hallwayscenter line segment
|-
! scope="row" | nxsub_len| integer real numeric| -meters | 5 0.1 | number length of rooms along Xsubstrate
|-
! scope="row" | nysub_wid| integer real numeric| -meters | 3 0.05 | number width of rooms along Ysubstrate
|-
! scope="row" | nzdraw_substrate| integer numericBoolean
| -
| 2 True | number of floors (number of rooms along Z)Adds substrate & ground plane|}Â [[EM.Picasso|EM.PICASSO]] TWO-PORT MICROSTRIP WIZARD PARAMETERS{| border="0"
|-
| valign="top"||-{| class="wikitable"|-! scope="col"| Parameter Name! scope="col"| Value Type! scope="col"| Units! scope="col"| Default Value! scope="col"| Notes|-! scope="row" | erh
| real numeric
| -meters | 40.40015 | relative permittivity of building wallssubstrate height (thickness)
|-
! scope="row" | siger
| real numeric
| S/m- | 1e-32.2 | conductivity of building wallssubstrate relative permittivity
|-
! scope="row" | wall_thicknessz0
| real numeric
| meterOhms | 50 | characteristic impedance |-! scope="row" | center_len| real numeric| meters | 0.05 | length of center line segment |-! scope="row" | feed_len| real numeric| meters | 0.255 * center_len | thickness length of the individual wallsfeed line
|}
<tr>
<td>
[[Image:wiz_officewiz_us2p_tempo.png|thumb|500px|Default office building scene two-port microstrip line segment in EM.Terrano with its rooms Tempo.]]</td></tr><tr><td>[[Image:wiz_us2p_picasso.png|thumb|500px|Default two-port microstrip line segment in the freeze stateEM.Picasso.]]
</td>
</tr>
</table>
== Hilly Terrain Two-Port Rectangular Waveguide Wizard ==
ICON: [[File:hill_iconwg2p icon.png]]
MENU: '''Tools → Propagation Transmission Line Wizards → Hilly TerrainTwo-Port Rectangular Waveguide'''
MODULE(S): [[EM.TerranoTempo]]
FUNCTION: Creates the parameterized geometry of a hilly terrain with a random rough surface in two-port rectangular waveguide segment slightly above the cutoff at the center frequency of the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a hilly terrain using a surface object generated with a Gaussian profileThe width of the waveguide is set slightly larger than half its cutoff wavelength for the dominant TE10 mode. The surface height is then roughened based on set equal to half its width. Both the specified statisticswidth and height can be replaced by arbitrary numeric values.
PYTHON COMMAND(S): emag_hillemag_rect_waveguide_2port(area_sizewg_len,heightfeed_len,radius,elevation,res,rms_height,correl_lenport_offset)
HILLY TERRAIN TWO-PORT WAVEGUIDE WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | area_sizewg_len
| real numeric
| metermeters | 500.5 | dimensions length of the square terrain surfacemiddle waveguide segment
|-
! scope="row" | heightfeed_len
| real numeric
| metermeters | 150.25 | height length of the hillfeed waveguide segments
|-
! scope="row" | radiusport_offset
| real numeric
| metermeters | 200.15 | radius of distance between port planes and the Gaussian surface profile|-! scope="row" | elevation| real numeric| meter| 1| base elevation of whole terrain surface |-! scope="row" | res| real numeric| meter| 5| resolution of terrain surface |-! scope="row" | rms_height| real numeric| meter| 1| RMS height of the random rough surface |-! scope="row" | correl_len| real numeric| meter| 5| correlation length open ends of the random rough surface waveguide
|}
<tr>
<td>
[[Image:wiz_hillwiz_wg2p_tempo.png|thumb|500px|Default hilly terrain two-port rectangular waveguide segment in EM.TerranoTempo with the two open-end feed sections in the freeze state.]]
</td>
</tr>
</table>
== Mountainous Terrain Two-Port Stripline Wizard ==
ICON: [[File:mountain_iconus2p icon.png]]
MENU: '''Tools → Propagation Transmission Line Wizards → Mountainous TerrainTwo-Port Stripline'''
MODULE(S): [[EM.TerranoTempo]], [[EM.Picasso]]
FUNCTION: Creates the parameterized geometry of a mountainous terrain with two-port stripline segment of a random rough surface specified characteristic impedance on a conductor-backed single-layer dielectric substrate in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a mountainous terrain using a surface object generated with a bi-cubic spline profileIn [[EM.Tempo]], the two ports are placed at the two edges of the substrate. The surface width of the Stripline is then roughened determined based on the specified statisticscharacteristic impedance. This wizard can It may be used to create either a mountain range with three peaks or replaced by a single-peak mountainnumeric value instead.
PYTHON COMMAND(S): emag_mountain emag_stripline_2port_tempo(is_rangeht,area_sizeert,heighthb,height_differb,radiusfeed_wid,spacingcetner_len,elevationsub_len,res,rms_height,correl_lensub_wid)
emag_stripline_2port_picasso(ht,ert,hb,erb,feed_wid,center_len)
MOUNTAINOUS TERRAIN [[EM.Tempo|EM.TEMPO]] TWO-PORT STRIPLINE WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | is_rangeht| Booleanreal numeric| -meters | True 0.0015 | if true, creates a mountain range with three peaks, otherwise, creates a single peak top substrate height (thickness)
|-
! scope="row" | area_sizeert
| real numeric
| meter- | 2002.2 | dimensions of the square terrain surfacetop substrate relative permittivity
|-
! scope="row" | heighthb
| real numeric
| metermeters | 2000.0015 | bottom substrate height of the hill(thickness)
|-
! scope="row" | height_differb
| real numeric
| meter- | 402.2 | difference between the heights of the center peak and the two lateral peaks in the case of a mountain rangebottom substrate relative permittivity
|-
! scope="row" | radiusfeed_wid
| real numeric
| metermeters| 500.002 | radius width of the bi-cubic spline surface profilefeed line segment
|-
! scope="row" | spacingcenter_wid
| real numeric
| metermeters| 70feed_wid| spacing between the center peak and the two lateral peaks in the case width of a mountain rangecenter line segment
|-
! scope="row" | elevationcenter_len
| real numeric
| metermeters | 10.03 | base elevation length of whole terrain surface center line segment
|-
! scope="row" | ressub_len
| real numeric
| metermeters | 50.1 | resolution length of terrain surface substrate
|-
! scope="row" | rms_heightsub_wid
| real numeric
| metermeters | 10.05 | RMS height width of the random rough surface substrate |}Â [[EM.Picasso|EM.PICASSO]] TWO-PORT STRIPLINE WIZARD PARAMETERS{| border="0"
|-
| valign="top"||-{| class="wikitable"|-! scope="col"| Parameter Name! scope="col"| Value Type! scope="col"| Units! scope="col"| Default Value! scope="col"| Notes|-! scope="row" | correl_lenht
| real numeric
| metermeters | 50.0015 | top substrate height (thickness) |-! scope="row" | ert| real numeric| - | 2.2 | top substrate relative permittivity |-! scope="row" | hb| real numeric| meters | 0.0015 | bottom substrate height (thickness) |-! scope="row" | erb| real numeric| - | 2.2 | bottom substrate relative permittivity |-! scope="row" | feed_wid| real numeric| meters| 0.002 | width of feed line segment |-! scope="row" | center_wid| real numeric| meters| feed_wid| width of center line segment |-! scope="row" | center_len| real numeric| meters | 0.03 | correlation length of the random rough surface center line segment |-! scope="row" | feed_len| real numeric| meters | 0.5 * center_len | length of feed line segment
|}
<tr>
<td>
[[Image:wiz_mountainWiz strpln2p tempo.png|thumb|500px|Default mountainous terrain two-port stripline segment in EM.TerranoTempo.]]</td></tr><tr><td>[[Image:Wiz strpln2p picasso.png|thumb|500px|Default two-port stripline segment in EM.Picasso.]]
</td>
</tr>
</table>
== Plateau Terrain Yagi-Uda Array Wizard ==
ICON: [[File:plateau_iconyagi icon.png]]
MENU: '''Tools → Propagation Antenna Wizards → Plateau TerrainYagi-Uda Dipole Array'''
MODULE(S): [[EM.TerranoLibera]]
FUNCTION: Creates the parameterized geometry of a plateau terrain with a random rough surface Yagi-Uda wire dipole array in the project workspace
NOTES, SPECIAL CASES OR EXCEPTIONS: This wizard creates a plateau terrain using a surface object generated with a bi-sigmoid profile. The surface is then roughened based on the specified statisticsdipole elements are all thin wires.
PYTHON COMMAND(S): emag_plateauemag_yagi(area_sizeexcite_len_lambda,heightreflect_len_lambda,slopereflect_spacing_lambda,elevationdirect_len_lambda,resdirect_spacing_lambda,rms_heightn_direct,correl_lenwire_rad_lambda)
PLATEAU TERRAIN YAGI WIZARD PARAMETERS
{| border="0"
|-
! scope="col"| Notes
|-
! scope="row" | area_sizeexcite_len_lambda
| real numeric
| meter-| 2000.47 | dimensions length of the square terrain surfaceexciter dipole normalized to free-space wavelength
|-
! scope="row" | heightreflect_len_lambda
| real numeric
| meter-| 100.5 | height length of the hillreflector dipole normalized to free-space wavelength
|-
! scope="row" | slopereflect_spacingn_lambda
| real numeric
| meter-| 0.125 | slope of the bispacing between reflector and exciter dipoles normalized to free-sigmoid surface profilespace wavelength
|-
! scope="row" | elevationdirect_len_lambda
| real numeric
| meter-| 0.5406 | base elevation length of whole terrain surface director dipoles normalized to free-space wavelength
|-
! scope="row" | resdirect_spacing_lambda
| real numeric
| meter-| 100.34 | resolution of terrain surface spacing between director dipoles normalized to free-space wavelength
|-
! scope="row" | rms_heightn_direct| real integer numeric| meter-| 0.5| RMS height number of the random rough surface director dipole elements along X
|-
! scope="row" | correl_lenwire_rad_lambda
| real numeric
| meter-| 100.003 | correlation length of the random rough surface wire radius normalized to free-space wavelength
|}
<tr>
<td>
[[Image:wiz_plateauwiz_yagi.png|thumb|500px|Default plateau terrain thin wire Yagi-Uda dipole array in EM.TerranoLibera.]]
</td>
</tr>
<hr>
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