Changes

<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 /> == Standard Python Operators == {| class="wikitable"!scope="col"| Syntax!scope="col"| Type!scope="col"| Description|-| style="width:80px;" | -p| style="width:150px;" | Std. Python operator| style="width:270px;" | negative of p|-| style="width:80px;" | p=q| style="width:150px;" | Std. Python operator| style="width:270px;" | p is equal to q|-| style="width:80px;" | p+q| style="width:150px;" | Std. Python operator| style="width:270px;" | sum of p and q|-| style="width:80px;" | p-q| style="width:150px;" | Std. Python operator| style="width:270px;" | difference p and q|-| style="width:80px;" | p*q| style="width:150px;" | Std. Python operator| style="width:270px;" | product of p and q|-| style="width:80px;" | p/q| style="width:150px;" | Std. Python operator| style="width:270px;" | quotient of p over q|-| style="width:80px;" | p**q| style="width:150px;" | Std. Python operator| style="width:270px;" | p to the power of q|-| style="width:80px;" | p%q| style="width:150px;" | Std. Python operator| style="width:270px;" | p modulus q|-| style="width:80px;" | p==q| style="width:150px;" | Std. Python operator| style="width:270px;" | p logically equal to q|-| style="width:80px;" | p>q| style="width:150px;" | Std. Python operator| style="width:270px;" | p is greater than q|-| style="width:80px;" | p>=q| style="width:150px;" | Std. Python operator| style="width:270px;" | p is greater than or equal to q|-| style="width:80px;" | p<q| style="width:150px;" | Std. Python operator| style="width:270px;" | p is less than q|-| style="width:80px;" | p<=q| style="width:150px;" | Std. Python operator| style="width:270px;" | p is less than or equal to q|-| style="width:80px;" | !p| style="width:150px;" | Std. Python operator| style="width:270px;" | Logical not p|-| style="width:80px;" | p and q| style="width:150px;" | Std. Python operator| style="width:270px;" | p Boolean and q|-| style="width:80px;" | p or q| style="width:150px;" | Std. Python operator| style="width:270px;" | p Boolean or q|-|} == Basic Mathematical Python Functions ==

| For for integer values of x: n! = n(n-1)(n-2)...3.2.1

| asinhnp.arcsinh(x)

| acoshnp.arccosh(x)

| atanhnp.arctanh(x)

| style="width:270px;" | See see [https://en.wikipedia.org/wiki/Trigonometric_integral Trigonometric Integrals on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Fresnel_integral Fresnel Integrals on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Elliptic_integral Elliptic Integrals on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Elliptic_integral Elliptic Integrals on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Exponential_integral Exponential Integrals on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Exponential_integral Exponential Integrals on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Error_function Error Function on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Error_function Error Function on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Gamma_function Gamma Function on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Airy_function Airy Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Bessel_function Bessel Functions on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Legendre_polynomial Legendre Polynomials on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Legendre_polynomials Legendre Polynomials on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Legendre_polynomial Legendre Polynomials on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Legendre_polynomials Legendre Polynomials on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Chebyshev_polynomials Chebyshev Polynomials on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Chebyshev_polynomials Chebyshev Polynomials on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Legendre_polynomials Legendre Polynomials on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Laguerre_polynomials Laguerre Polynomials on Wikipedia.]

| See see [https://en.wikipedia.org/wiki/Hermite_polynomials Hermite Polynomials on Wikipedia.]

| Math_cesp.mathieu_cem(n,rq,x)

| Even periodic (cosine) Mathieu function of order nand its derivative| See see [https://en.wikipedia.org/wiki/Mathieu_function Mathieu Functions on Wikipedia.]

| Math_sesp.mathieu_sem(n,rq,x)

| Odd periodic (sine) Mathieu function of order nand its derivative| See see [https://en.wikipedia.org/wiki/Mathieu_function Mathieu Functions on Wikipedia.]

== EM.Cube's Miscellaneous Native Python Functions ==

{| class="wikitable"!scope="col"| Syntax!scope="col"| Type!scope="col"| Description!scopeactivate="col"| Notes|-| style="width:80px;" | rect(x)| style="width:150px;" | EMAG Python function| style="width:270px;" | Rectangle function| style="width:270px;" | 1 if |x|&le;0.5, 0 elsewhere |-| tri(x)| EMAG Python function| Triangle function| 1 if |1-x|&le;1, 0 elsewhere |-| spline2(x)| EMAG Python function| Quadratic spline function| -|-| spline3(x)| EMAG Python function| Cubic spline function| -|-| step(x)| EMAG Python function| Step function| 1 if x>0, 0 if x<0|-| sgn(x)| Std. Python function| Sign function| 1 if x>0, -1 if x<0|-| ramp(x)| EMAG Python function| Ramp function| -|-| sqr_wave(x)| EMAG Python function| Square wave function| -|-| tri_wave(x)| EMAG Python function| Triangle wave function| -|-| sawtooth(x)| EMAG Python function| Sawtooth wave function| -|-| sinc(x)| EMAG Python function| Sinc function| sin(pi*x)/(pi*x)|-| gauss(x)| Std. Python function| Gaussian function| -|-| rand(x,y)| EMAG Python function| Random function| -|}

{| class=EXAMPLE: ''activate("wikitableColor_1")'' DESCRIPTION: Activates a color, material or object group in the current active [[EM.Cube]] module for insertion of new objects.  !scope====add_variable==== SYNTAX: add_variable({{ArgTypeString}} var_name, {{ArgTypeAny}} value) EXAMPLE: ''add_variable("colMyVar"| Syntax,1)'' DESCRIPTION: Adds a new variable to [[EM.Cube]]'s variable list. !scope====array==== SYNTAX: array({{ArgTypeString}} label, {{ArgTypeString}} object, {{ArgTypeAny}} x_count, {{ArgTypeAny}} y_count, {{ArgTypeAny}} z_count, {{ArgTypeAny}} x_spacing, {{ArgTypeAny}} y_spacing, {{ArgTypeAny}} z_spacing) EXAMPLE: ''array("colArray_1"| Type,"Rect_Strip_1",4,4,1,50,50,0)'' DESCRIPTION: Creates or modifies an array object. !scope====array_custom==== SYNTAX: array_custom({{ArgTypeString}} label, {{ArgTypeString}} object, {{ArgTypeAny}} x_count, {{ArgTypeAny}} y_count, {{ArgTypeAny}} z_count, {{ArgTypeAny}} x_spacing, {{ArgTypeAny}} y_spacing, {{ArgTypeAny}} z_spacing, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} rot_x, {{ArgTypeAny}} rot_y, {{ArgTypeAny}} rot_z) EXAMPLE: ''array_custom("colArray_1"| Description,"Rect_Strip_1",4,4,1,50,50,0,100,100,20,0,0,45)'' DESCRIPTION: Creates or modifies an array object and sets its local coordinate system and rotation angles. !scope====background_layer==== SYNTAX: background_layer({{ArgTypeString}} label, {{ArgTypeAny}} eps, {{ArgTypeAny}} sigma, {{ArgTypeAny}} mu, {{ArgTypeAny}} thickness) EXAMPLE: ''background_layer("colMid_Layer"| Notes,3.3,0.001,1,1.5)'' DESCRIPTION: Adds a new substrate layer to [[EM.Picasso]]'s background layer stackup.|-| style="width===base_point_group==== SYNTAX:100px;base_point_group({{ArgTypeString}} label) EXAMPLE: ''base_point_set(" | microstrip_designBP_Set_1")'' DESCRIPTION: Creates a base point set in [[EM.Terrano]]. If the base point set group 'label' already exists, the group is activated. ====bh_step==== SYNTAX: bh_step(z0{{ArgTypeReal}} x,er{{ArgTypeReal}} T)| styleEXAMPLE: ''bh_step(0.5,1)'' DESCRIPTION: Computes and returns the Blackman-Harris step function. ="width===bh_window==== SYNTAX:150px;" | EMAG Python bh_window({{ArgTypeReal}} x, {{ArgTypeReal}} T) EXAMPLE: ''bh_window(0.5,1)'' DESCRIPTION: Computes and returns the Blackman-Harris window function. | style="width===box==== SYNTAX:250px;box({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} base_x, {{ArgTypeAny}} base_y, {{ArgTypeAny}} height[, {{ArgTypeAny}} cap_top, {{ArgTypeAny}} cap_bottom]) EXAMPLE: ''box(" | Returns Box_1",0,0,0,50,50,100)'' DESCRIPTION: Draws a box object in the widthproject workspace under the currently activated material group node, or modifies the box named 'label' if it already exists. ====capacitance==== SYNTAX: capacitance({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2, {{ArgTypeAny}} x3, {{ArgTypeAny}} y3, {{ArgTypeAny}} z3, {{ArgTypeAny}} x4, {{ArgTypeAny}} y4, {{ArgTypeAny}} z4) EXAMPLE: ''capacitance("FI_1",-to10,-height ratio of 10,5,10,10,10,0,0,-10,0,0,10)'' DESCRIPTION: Creates a microstrip transmission line capacitance integral observable in [[EM.Ferma]]. If the observable 'label' already exists, its properties are modified. | style="width===capacitor==== SYNTAX:250px;capacitor({{ArgTypeString}} label, {{ArgTypeAny}} line_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} capacitance_pF) EXAMPLE: ''capacitor(" | z0Cap_1","Line_1",25,10)'' DESCRIPTION: characteristic impedance Creates a capacitor in Ohms[[EM.Tempo]]. If the capacitor 'label' already exists, erits properties are modified. ====charge_group==== SYNTAX: substrate permittivitycharge_group({{ArgTypeString}} label, {{ArgTypeAny}} density)|EXAMPLE: ''charge_group("Charge_1",-1e-5)'' DESCRIPTION: Creates a volume charge source group in [[EM.Ferma]]. If the charge group 'label' already exists, the group is activated. | style="width===circ_strip==== SYNTAX:100px;" | microstrip_z0circ_strip(w{{ArgTypeString}} label,h{{ArgTypeAny}} x0,er{{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} inner_radius, {{ArgTypeAny}} outer_radius[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle])| style=EXAMPLE: ''circ_strip("widthcs_1",0,0,0,50,0)'' DESCRIPTION:150px;Draws a circle strip object in the project workspace under the currently activated material group node, or modifies the circle strip object named 'label' if it already exists. The arguments start_angle and end_angle are in degrees and specify a sweep about the circle strip's azimuth axis. ====circle==== SYNTAX: circle({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle) EXAMPLE: ''circle(" | EMAG Python functionpyramid_1",0,0,0,10,10,100)'' DESCRIPTION: Draws a circular curve object in the project workspace under the currently activated material group node, or modifies the circle named 'label' if it already exists. The parameters start_angle and end_angle are in degrees. | style====clone==== SYNTAX: clone({{ArgTypeString}} label, {{ArgTypeString}} object, {{ArgTypeReal}} x0, {{ArgTypeReal}} y0, {{ArgTypeReal}} z0) EXAMPLE: ''clone("widthNewObj","MyObj",10,10,0)'' DESCRIPTION:250px;Creates a copy of the specified object and repositions it at the given coordinates.  ====close_curve==== SYNTAX: close_curve({{ArgTypeString}} label, {{ArgTypeString}} close_state) EXAMPLE: ''close_curve(" | Returns Curve_1",1)'' DESCRIPTION: Sets the characteristic impedance open/close state of a microstrip polyline or NURBS curve. Use 0 for open curve and 1 for close curve. ====coaxial_design==== SYNTAX: coaxial_design({{ArgTypeReal}} z0, {{ArgTypeReal}} er) EXAMPLE: ''coaxial_design(50,2.2)'' DESCRIPTION: Computes and returns the ratio of the radius of the outer conductor to the radius of the inner conductor of a coaxial transmission line of characteristic impedance z0 (in Ohms ) with core relative permittivity er. | style="width===coaxial_src==== SYNTAX:250px;coaxial_src({{ArgTypeString}} label, {{ArgTypeAny}} cylinder_object, {{ArgTypeAny}} outer_radius, {{ArgTypeAny}} edge[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]) EXAMPLE: ''coaxial_src(" | wCOAX_1","Cyl_1",1.5,"+z")'' DESCRIPTION: microstrip widthCreates a coaxial port source in [[EM.Tempo]]. If the coaxial port 'label' already exists, hits properties are modified. ====color_group==== SYNTAX: substrate heightcolor_group({{ArgTypeString}} label) EXAMPLE: ''color_group("Color_1")'' DESCRIPTION: Creates a color group in CubeCAD module. If the color group 'label' already exists, erthe group is activated. ====conduction_current_integral==== SYNTAX: substrate permittivityconduction_current_integral({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2)|EXAMPLE: ''conduction_current_integral("FI_1",-10,-10,0,10,10,0)'' DESCRIPTION: Creates a conduction current integral observable in [[EM.Ferma]]. If the observable 'label' already exists, its properties are modified. | style="width===conductive_sheet_group==== SYNTAX:100px;" | microstrip_eps_effconductive_sheet_group(w{{ArgTypeString}} label,h{{ArgTypeAny}} sigma,er{{ArgTypeAny}} thickness)| style="widthEXAMPLE:150px;''conductive_sheet_group(" | EMAG Python functionCond_1",100, 0.01)'' DESCRIPTION: Creates a conductive sheet group in [[EM.Picasso]]. If the conductive sheet group 'label' already exists, the group is activated. | style="width===cone==== SYNTAX:250px;cone({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} base_radius, {{ArgTypeAny}} height[, {{ArgTypeAny}} top_radius, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle, {{ArgTypeAny}} cap_top, {{ArgTypeAny}} cap_bottom]) EXAMPLE: ''cone(" | Returns Cone_1",0,0,0,30,40,20,0,180)'' DESCRIPTION: Draws a cone object in the effective permittivity of project workspace under the currently activated material group node, or modifies the cone named 'label' if it already exists. The arguments start_angle and end_angle are in degrees and specify a microstrip transmission line sweep about the cone's azimuth axis. | style="width===consolidate==== SYNTAX:250px;consolidate({{ArgTypeString}} object) EXAMPLE: ''consolidate(" | wPoly_1")'' DESCRIPTION: microstrip widthConsolidates a specified object. ====cpw_design_s==== SYNTAX: cpw_design_s({{ArgTypeReal}} z0, {{ArgTypeReal}} w, {{ArgTypeReal}} h: substrate height, {{ArgTypeReal}} er) EXAMPLE: ''cpw_design_s(50,2,0.5,2.2)'' DESCRIPTION: Computes and returns the center strip width (in meters) of a CPW transmission line of characteristic impedance z0 with slot width w, substrate height h and substrate relative permittivityer.|-| style="width===cpw_design_w==== SYNTAX:100px;" | microstrip_lambda_gcpw_design_w(w{{ArgTypeReal}} z0,{{ArgTypeReal}} s, {{ArgTypeReal}} h,{{ArgTypeReal}} er) EXAMPLE: ''cpw_design_w(50,freq_hertz1,0.5,2.2)''| style="DESCRIPTION: Computes and returns the slot width(in meters) of a CPW transmission line of characteristic impedance z0 with center strip width s, substrate height h and substrate relative permittivity er. ====cpw_src==== SYNTAX:150px;cpw_src({{ArgTypeString}} label, {{ArgTypeAny}} rect_object, {{ArgTypeAny}} spacing, {{ArgTypeAny}} edge[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]) EXAMPLE: ''cpw_src(" | EMAG Python functionCPW_1","Rect_1",1.5,"+x")'' DESCRIPTION: Creates a CPW port source in [[EM.Tempo]]. If the CPW port 'label' already exists, its properties are modified. | style="width===cubecad_mesh_settings==== SYNTAX:250px;" | Returns cubecad_mesh_settings({{ArgTypeAny}} edge_length, {{ArgTypeAny}} angle_tol) EXAMPLE: ''cubecad_mesh_settings(5,10)'' DESCRIPTION: Sets the guide wavelength parameters of CubeCAD's mesh generator. ====current_dist==== SYNTAX: current_dist({{ArgTypeString}} label) EXAMPLE: ''current_dist("CD_1")'' DESCRIPTION: Creates a microstrip transmission line current distribution observable. If the observable 'label' already exists, its properties are modified. ====current_integral==== SYNTAX: current_integral({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2) EXAMPLE: ''current_integral("FI_1",-10,-10,0,10,10,0)'' DESCRIPTION: Creates a current integral observable in meters[[EM.Ferma]]. If the observable 'label' already exists, its properties are modified. | style====cylinder==== SYNTAX: cylinder({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius, {{ArgTypeAny}} height[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle, {{ArgTypeAny}} cap_top, {{ArgTypeAny}} cap_bottom]) EXAMPLE: ''cylinder("widthCylinder_1",0,0,0,10,100)'' DESCRIPTION:250px;Draws a cylinder object in the project workspace under the currently activated material group node, or modifies the cylinder named 'label' if it already exists. The arguments start_angle and end_angle are in degrees and specify a sweep about the cylinder's azimuth axis. ====delete==== SYNTAX: delete({{ArgTypeString}} node_name) EXAMPLE: ''delete(" | wBox_1")'' DESCRIPTION: microstrip widthDeletes a node name from the navigation tree. The node can be any geometric object, hsource, observable or material group.  ====delete_background_layer==== SYNTAX: delete_background_layer({{ArgTypeString}} label) EXAMPLE: ''delete_background_layer("Mid_Layer")'' DESCRIPTION: Deletes a finite-thickness substrate heightlayer from [[EM.Picasso]]'s background layer stackup. ====dielectric_group==== SYNTAX: dielectric_group({{ArgTypeString}} label, er{{ArgTypeAny}} eps, {{ArgTypeAny}} sigma, {{ArgTypeAny}} mu, {{ArgTypeAny}} rho) EXAMPLE: substrate permittivity''dielectric_group("Dielectric_1", freq_hertz"my_eps",0,1,0)'' DESCRIPTION: frequency Creates a dielectric material group in Hzthe current module with the specified material properties. If the dielectric group 'label' already exists, the group is activated.|-| style====diode==== SYNTAX: diode({{ArgTypeString}} label, {{ArgTypeAny}} line_object, {{ArgTypeAny}} polarity, {{ArgTypeAny}} is_fA, {{ArgTypeAny}} temperature_K, {{ArgTypeAny}} ideality_factor) EXAMPLE: ''diode("widthDiode_1","Line_1",25,0,10,300,1)'' DESCRIPTION:100px;Creates a diode in [[EM.Tempo]]. If the diode 'label' already exists, its properties are modified. ====distributed_src==== SYNTAX: distributed_src({{ArgTypeString}} label, {{ArgTypeAny}} rect_object, {{ArgTypeAny}} field_dir, {{ArgTypeAny}} profile[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]) EXAMPLE: ''distributed_src(" | cpw_design_wDS_1","Rect_1","+y","uniform")'' DESCRIPTION: Creates a distributed source in [[EM.Tempo]]. If the distributed source 'label' already exists, its properties are modified. ====ellipse_strip==== SYNTAX: ellipse_strip({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0,{{ArgTypeAny}} radius_x, {{ArgTypeAny}} radius_y[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle]) EXAMPLE: ''ellipse_strip("es_1",0,0,0,50,0)'' DESCRIPTION: Draws a ellipse strip object in the project workspace under the currently activated material group node, or modifies the ellipse strip object named 'label' if it already exists. The arguments start_angle and end_angle are in degrees and specify a sweep about the ellipse strip'sazimuth axis. ====ellipsoid==== SYNTAX: ellipsoid({{ArgTypeString}} label,h{{ArgTypeAny}} x0,er{{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius_x, {{ArgTypeAny}} radius_y, {{ArgTypeAny}} radius_z[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle])| styleEXAMPLE: ''ellipsoid("Ellipsoid_1",0,0,0,100,100,50,0,360)'' DESCRIPTION: Draws an ellipsoid object in the project workspace under the currently activated material group node, or modifies the ellipsoid named 'label' if it already exists. The arguments start_angle and end_angle are in degrees and specify a sweep about the ellipsoid's azimuth axis. ====emferma_engine_settings==== SYNTAX: emferma_engine_settings({{ArgTypeString}} matrix_solver, {{ArgTypeAny}} error_tol, {{ArgTypeAny}} max_iterations) EXAMPLE: ''emferma_engine_settings("widthbicg-stab",1e-3,100)'' DESCRIPTION:150px;Sets the parameters of [[EM.Ferma]]'s electrostatic and magnetostatic simulation engines. ====emferma_mesh_settings==== SYNTAX: emferma_mesh_settings({{ArgTypeAny}} cell_size_x, {{ArgTypeAny}} cell_size_y, {{ArgTypeAny}} cell_size_z) EXAMPLE: ''emferma_mesh_settings(0.5,0.5,0.5)'' DESCRIPTION: Sets the parameters of [[EM.Ferma]]'s fixed-cell mesh generator. ====emillumina_engine_settings==== SYNTAX: emillumina_engine_settings({{ArgTypeString}} engine, {{ArgTypeAny}} is_fixed_iteration, {{ArgTypeAny}} error_tol, {{ArgTypeAny}} max_iterations) EXAMPLE: ''emillumina_engine_settings(" | EMAG Python functionipo",0,1e-2,20)'' DESCRIPTION: Sets the parameters of [[EM.Illumina]]'s Physical Optics simulation engine. | style====emillumina_mesh_settings==== SYNTAX: emillumina_mesh_settings({{ArgTypeAny}} cells_per_lambda) EXAMPLE: ''emillumina_mesh_settings(30)'' DESCRIPTION: Sets the parameters of [[EM.Illumina]]'s mesh generator. ====emlibera_engine_settings_smom==== SYNTAX: emlibera_engine_settings_smom({{ArgTypeString}} matrix_solver, {{ArgTypeAny}} error_tol, {{ArgTypeAny}} max_iterations, {{ArgTypeAny}} ncpus, {{ArgTypeString}} formulation, {{ArgTypeAny}} alpha) EXAMPLE: ''emlibera_engine_settings_smom("widthbicg",1e-3,1000,4,"efie",0.4)'' DESCRIPTION:250px;Sets the parameters of [[EM.Libera]]'s surface MoM simulation engines. ====emlibera_engine_settings_wmom==== SYNTAX: emlibera_engine_settings_wmom({{ArgTypeString}} matrix_solver, {{ArgTypeAny}} error_tol, {{ArgTypeAny}} max_iterations) EXAMPLE: ''emlibera_engine_settings_wmom(" | Returns bicg",1e-3,1000)'' DESCRIPTION: Sets the slot width parameters of a coplanar waveguide [[EM.Libera]]'s wire MoM simulation engines. ====emlibera_mesh_settings==== SYNTAX: emlibera_mesh_settings(CPW{{ArgTypeAny}} cells_per_lambda) transmission line | styleEXAMPLE: ''emlibera_mesh_settings(30)'' DESCRIPTION: Sets the parameters of [[EM.Libera]]'s mesh generator. ====empicasso_engine_settings==== SYNTAX: empicasso_engine_settings({{ArgTypeString}} matrix_solver, {{ArgTypeAny}} error_tol, {{ArgTypeAny}} max_iterations) EXAMPLE: ''empicasso_engine_settings("widthbicg",1e-3,1000)'' DESCRIPTION:250px;Sets the parameters of [[EM.Picasso]]'s planar MoM simulation engine. ====empicasso_mesh_settings==== SYNTAX: empicasso_mesh_settings({{ArgTypeAny}} cells_per_lambda) EXAMPLE: ''empicasso_mesh_settings(30)'' DESCRIPTION: Sets the parameters of [[EM.Picasso]]'s planar hybrid mesh generator. ====emtempo_engine_settings==== SYNTAX: emtempo_engine_settings({{ArgTypeString}} engine, {{ArgTypeAny}} power_threshhold, {{ArgTypeAny}} max_timesteps) EXAMPLE: ''emtempo_engine_settings(" | z0single-precision",-50,20000)'' DESCRIPTION: characteristic impedance in OhmsSets the parameters of [[EM.Tempo]]'s FDTD simulation engine. ====emtempo_mesh_settings==== SYNTAX: emtempo_mesh_settings({{ArgTypeAny}} cells_per_lambda, {{ArgTypeAny}} ratio_contour, {{ArgTypeAny}} ratio_thin, {{ArgTypeAny}} ratio_abs) EXAMPLE: ''emtempo_mesh_settings(30,0.1,0.1,0.02)'' DESCRIPTION: Sets the parameters of [[EM.Tempo]]'sadaptive mesh generator. ====emterrano_engine_settings==== SYNTAX: center strip width emterrano_engine_settings(or slot spacing{{ArgTypeAny}} bounce_count, {{ArgTypeAny}} do_edge_diffraction, {{ArgTypeAny}} angular_resolution, {{ArgTypeAny}} ray_threshhold) EXAMPLE: ''emterrano_engine_settings(5, h1,1,-100)'' DESCRIPTION: substrate heightSets the parameters of [[EM.Terrano]]'s SBR simulation engine. ====emterrano_mesh_settings==== SYNTAX: emterrano_mesh_settings({{ArgTypeAny}} edge_length, er{{ArgTypeAny}} angle_tol) EXAMPLE: substrate permittivity''emterrano_mesh_settings(5,10)'' DESCRIPTION: Sets the parameters of [[EM.Terrano]]'s facet mesh generator.|-| style="width===energy_electric==== SYNTAX:100px;energy_electric({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2) EXAMPLE: ''energy_electric(" | cpw_design_sFI_1",-10,-10,-10,10,10,10)'' DESCRIPTION: Creates an electric energy integral observable in [[EM.Ferma]]. If the observable 'label' already exists, its properties are modified. ====energy_magnetic==== SYNTAX: energy_magnetic(z0{{ArgTypeString}} label,w{{ArgTypeAny}} x1,h{{ArgTypeAny}} y1,er{{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2)| styleEXAMPLE: ''energy_magnetic("FI_1",-10,-10,-10,10,10,10)'' DESCRIPTION: Creates a magnetic energy integral observable in [[EM.Ferma]]. If the observable 'label' already exists, its properties are modified. ====explode==== SYNTAX: explode({{ArgTypeString}} object) EXAMPLE: ''explode("widthMyArray")'' DESCRIPTION:150px;Explodes an object into its basic primitives. ====export_dxf==== SYNTAX: export_dxf({{ArgTypeString}} file_name) EXAMPLE: ''export_dxf(" | EMAG Python functionMyDXFModel.DXF")'' DESCRIPTION: Exports the physical structure of the project workspacean to a DXF model file. If the file path is not specified, the current project folder is assumed as the path. | style====export_py==== SYNTAX: export_py({{ArgTypeString}} file_name) EXAMPLE: ''export_py("widthMyPYModel.PY")'' DESCRIPTION:250pxExports the physical structure of the project workspace or the current object selection to a Python geometry file. The default path is the Python subfolder under "Documents &rarr;EMAG" | Returns the center strip width . ====export_stl==== SYNTAX: export_stl(or slot spacing{{ArgTypeString}} file_name)  EXAMPLE: ''export_stl("MySTLModel.STL")'' DESCRIPTION: Exports the physical structure of a coplanar waveguide the project workspacean to an STL model file. If the file path is not specified, the current project folder is assumed as the path. ====extrude==== SYNTAX: extrude(CPW{{ArgTypeString}} label, {{ArgTypeString}} object, {{ArgTypeAny}} extrude_height, {{ArgTypeAny}} cap_ends) transmission line  EXAMPLE: ''extrude("Extrude_1","Rect_Strip1",50)'' DESCRIPTION: Creates or modifies an extrusion object from a specified object by the specified height. If modifying an existing extrusion object, the pre-existing primitive is used. This command can only extrude objects that have a single face and will extrude along the face's normal. | style="width===farfield==== SYNTAX:250px;farfield({{ArgTypeString}} label, {{ArgTypeAny}} theta_incr, {{ArgTypeAny}} phi_incr) EXAMPLE: ''farfield(" | FF_1",1,1)'' DESCRIPTION: Creates a far-field radiation pattern observable. If the observable 'label' already exists, its properties are modified. ====field_probe==== SYNTAX: field_probe({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0) EXAMPLE: characteristic impedance in Ohms''field_probe("FS_1", w0,0,50)'' DESCRIPTION: slot widthCreates a temporal field probe observable in [[EM.Tempo]] or [[EM.Ferma]]. If the observable 'label' already exists, hits properties are modified. ====field_sensor==== SYNTAX: substrate heightfield_sensor({{ArgTypeString}} label, er{{ArgTypeAny}} dir_coordinate, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} xSize, {{ArgTypeAny}} ySize, {{ArgTypeAny}} zSize, {{ArgTypeAny}} xSamples, {{ArgTypeAny}} ySamples, {{ArgTypeAny}} zSamples) EXAMPLE: substrate permittivity''field_sensor("FS_1","z",0,0,0,100,100,0,25,25,0)''|DESCRIPTION: Creates a near-field sensor observable. If the observable 'label' already exists, its properties are modified. | style====field_sensor_grid==== SYNTAX: field_sensor_grid({{ArgTypeString}} label, {{ArgTypeAny}} dir_coordinate, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0) EXAMPLE: ''field_sensor_grid("widthFS_1","z",0,0,0)'' DESCRIPTION:100px;Creates a near-field sensor observable in [[EM.Tempo]] or [[EM.Ferma]]. If the observable 'label' already exists, its properties are modified. ====fill_curve==== SYNTAX: fill_curve({{ArgTypeString}} object) EXAMPLE: ''fill_curve(" | coaxial_designCurve_1")'' DESCRIPTION: Fill the interior of the specified closed curve object. ====fillet==== fillet(z0{{ArgTypeString}} object,er{{ArgTypeAny}} radius)| styleEXAMPLE: ''fillet("Rect_1",5)'' DESCRIPTION: Fillets the corners of the specified surface or curve object by the specified radius. ====flux_electric==== SYNTAX: flux_electric({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2) EXAMPLE: ''flux_electric("widthFI_1",-10,-10,5,10,10,10)'' DESCRIPTION:150px;Creates an electric flux integral observable in [[EM.Ferma]]. If the observable 'label' already exists, its properties are modified. ====flux_magnetic==== SYNTAX: flux_magnetic({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2) EXAMPLE: ''flux_magnetic(" | EMAG Python functionFI_1",0,0,-10,10,0,10)'' DESCRIPTION: Creates a magnetic flux integral observable in [[EM.Ferma]]. If the observable 'label' already exists, its properties are modified. | style====fractal_tree==== SYNTAX: fractal_tree({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} key_type, {{ArgTypeAny}} key_size, {{ArgTypeAny}} n_level, {{ArgTypeAny}} sep_angle, {{ArgTypeAny}} n_gen, {{ArgTypeAny}} prune_factor, {{ArgTypeAny}} thickness, {{ArgTypeAny}} thick_factor) EXAMPLE: ''fractal_tree("widthFractal_1",0,0,0,"line",10,3,30,3,0,0,0)'' DESCRIPTION:250px;Generates a fractal tree in the project workspace under the currently activated material group node, or modifies the fractal tree named 'label' if it already exists. ====freeze==== SYNTAX: freeze({{ArgTypeString}} object, {{ArgTypeReal}} freeze_state) EXAMPLE: ''freeze(" | Returns MyObj",1)'' DESCRIPTION: Sets the ratio freeze state of an object (0/1).  ====gauss==== SYNTAX: gauss({{ArgTypeReal}} x, ArgTypeReal}} mu, ArgTypeReal}} sigma) EXAMPLE: ''gauss(0.5,0,1)'' DESCRIPTION: Computes and returns the Gaussian function of mean mu and standard deviation sigma: exp(-0.5*((x-mu)/sigma)**2)/sigma/sqrt(2*pi). ====gauss_beam==== SYNTAX: gauss_beam({{ArgTypeString}} label, {{ArgTypeAny}} theta, {{ArgTypeAny}} phi, {{ArgTypeAny}} polarization, {{ArgTypeAny}} focus_x, {{ArgTypeAny}} focus_y, {{ArgTypeAny}} focus_z, {{ArgTypeAny}} radius , {{ArgTypeAny}} p_mode, {{ArgTypeAny}} q_mode) EXAMPLE: ''gauss_beam("PW_1",180,0,"tm",0,0,0,20,0,0)'' DESCRIPTION: Creates a Gaussian beam source in [[EM.Tempo]]. If the Gaussian beam source 'label' already exists, its properties are modified. ====generate_input_files==== SYNTAX: generate_input_files() EXAMPLE: ''generate_input_files()'' DESCRIPTION: Generates all the input files for the simulation engine of the outer conductor to current module without running a simulation. ====geo==== SYNTAX: geo({{ArgTypeReal}} x, {{ArgTypeReal}} y) EXAMPLE: ''geo(1,2)'' DESCRIPTION: Computes and returns the radius geometric mean of x and y: sqrt(x*y). ====get_area==== SYNTAX: get_area({{ArgTypeString}} object) EXAMPLE: ''get_area("ellipse_1")'' DESCRIPTION: Returns the inner condutcor area of a coaxial transmission line surface object or the total surface area of a solid object. | style="width===get_axis==== SYNTAX:250px;" | z0get_axis({{ArgTypeString}} object, {{ArgTypeString}} axis, {{ArgTypeString}} coordinate) EXAMPLE: characteristic impedance in Ohms''get_axis("pyramid_1", er"x","y")'' DESCRIPTION: core permittivityReturns the specified coordinate of the unit vector along the specified local axis of an object.|-| style====get_domain_extent==== SYNTAX: get_domain_extent({{ArgTypeString}} coordinate) EXAMPLE: ''get_domain_extent("widthx")'' DESCRIPTION:100px;Returns the size of the computational domain along the specified direction. ====get_extent==== SYNTAX: get_extent({{ArgTypeString}} object, {{ArgTypeString}} coordinate) EXAMPLE: ''get_extent(" | waveguide_designpyramid_1","x")'' DESCRIPTION: Returns the size of the bounding box of an object along the specified direction. ====get_lcs==== SYNTAX: get_lcs(er{{ArgTypeString}} object,freq_hertz{{ArgTypeString}} coordinate)| styleEXAMPLE: ''get_lcs("pyramid_1","x")'' DESCRIPTION: Returns the specified coordinate of the LCS of an object. ====get_lcs_offset==== SYNTAX: get_lcs_offset({{ArgTypeString}} object, {{ArgTypeAny}} x_off, {{ArgTypeAny}} y_off, {{ArgTypeAny}} z_off, {{ArgTypeString}} coordinate) EXAMPLE: ''get_lcs_offset("widthbox_1",50,50,0,"x")'' DESCRIPTION:150px;Returns the specified coordinate of the LCS of an object after being translated by the specified offset values along the three principal axes. ====get_length==== SYNTAX: get_length({{ArgTypeString}} object) EXAMPLE: ''get_length(" | EMAG Python functionhelix_1")'' DESCRIPTION: Returns the length of a curve object. | style====get_rot==== SYNTAX: get_rot({{ArgTypeString}} object, {{ArgTypeString}} coordinate) EXAMPLE: ''get_rot("widthpyramid_1","x")'' DESCRIPTION:250px;Returns the specified rotation angle of an object. ====get_standard_output==== SYNTAX: get_standard_output({{ArgTypeString}} output_name)  EXAMPLE: ''get_standard_output(" | S11M")'' DESCRIPTION: Returns the minimum larger dimension in meter computed value of the cross section specified standard output parameter at the end of a hollow rectangular waveguide above cutoff simulation. | style====get_vertex==== SYNTAX: get_vertex({{ArgTypeString}} object, {{ArgTypeAny}} node_index, {{ArgTypeString}} coordinate) EXAMPLE: ''get_vertex("widthpyramid_1",0,"x")'' DESCRIPTION:250px;Returns the specified coordinate of the specified vertex of the bounding box of an object. The vertices are specified by node indices. The lower front left corner has an index of 0, while the upper back right corner has an index of 7. The indices are numbered counterclockwise, with the bottom face first and top face next.  ====get_volume==== SYNTAX: get_volume({{ArgTypeString}} object) EXAMPLE: ''get_volume(" | erpyramid_1")'' DESCRIPTION: filling permittivityReturns the volume of a solid object. ====global_ground==== SYNTAX: global_ground({{ArgTypeAny}} ground_on, freq_hertz{{ArgTypeAny}} eps, {{ArgTypeAny}} sigma) EXAMPLE: frequency in Hz''global_ground(1,3.3,0.001)''|-| styleDESCRIPTION: Set the state of [[EM.Terrano]]'s global ground and its material properties. A zero value for ground_on means to no global ground assumed at Z =0.  ====group==== SYNTAX: group({{ArgTypeString}} label, {{ArgTypeString}} object_1, {{ArgTypeString}} object_2, ...) EXAMPLE: ''group("widthComposite_1","Box_1","Box_2","Box_3")'' DESCRIPTION:100px;Groups a number of objects into a composite object with the given label. ====harm==== SYNTAX: harm({{ArgTypeReal}} x, {{ArgTypeReal}} y) EXAMPLE: ''harm(1,2)'' DESCRIPTION: Computes and returns the harmonic mean of x and y: 2/(1/x+1/y). ====helix==== SYNTAX: helix({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius_inner, {{ArgTypeAny}} radius_outer, {{ArgTypeAny}} nturns, {{ArgTypeAny}} helix_dir) EXAMPLE: ''helix(" | Helix_1",0,0,0,15,15,10,0)'' DESCRIPTION: Draws a helical curve in the project workspace under the currently activated material group node, or modifies the helix named 'label' if it already exists. The parameter "radius_inner" specifies the helix's radius at the beginning of the helix, and radius_outer specifies the radius at the end of the helix. If the Boolean parameter "helixl_dir" is 1, the helical curve will be drawn counter-clockwise. ====horn_design_a==== SYNTAX: horn_design_a({{ArgTypeReal}} D0_dB,{{ArgTypeReal}} a_lambda,{{ArgTypeReal}} b_lambda)| style="widthEXAMPLE:150px;" | EMAG Python function''horn_design_a(15,0.4,0.3)''| style="widthDESCRIPTION:250px;" | Returns Computes and returns the wavelength-normalized larger dimension of the aperture of an optimal pyramidal horn antenna with directivity D0_dB and wavelength-normalized feed waveguide dimensions a_lambda and b_lambda. | style="width===horn_design_b==== SYNTAX:250px;" | horn_design_b({{ArgTypeReal}} D0_dB: directivity d, {{ArgTypeReal}} a_lambda, {{ArgTypeReal}} b_lambda) EXAMPLE: ''horn_design_b(15,0.4,0.3)'' DESCRIPTION: Computes and returns the wavelength-normalized larger smaller dimension of the aperture of an optimal pyramidal horn antenna with directivity D0_dB and wavelength-normalized feed waveguidedimensions a_lambda and b_lambda. ====horn_design_l==== SYNTAX: horn_design_l({{ArgTypeReal}} D0_dB, {{ArgTypeReal}} a_lambda, {{ArgTypeReal}} b_lambda) EXAMPLE: ''horn_design_l(15,0.4,0.3)'' DESCRIPTION: Computes and returns the wavelength-normalized smaller dimension length of the an optimal pyramidal horn antenna with directivity D0_dB and wavelength-normalized feed waveguide dimensions a_lambda and b_lambda.|-| style====huygens_src==== SYNTAX: huygens_src({{ArgTypeString}} label, {{ArgTypeAny}} filename[, {{ArgTypeAny}} set_lcs, {{ArgTypeAny}} polarization, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} x_rot, {{ArgTypeAny}} y_rot, {{ArgTypeAny}} z_rot]) EXAMPLE: ''huygens_src("widthHS_1","Huygens_1.HUY",1,100,100,0,0,0,0)'' DESCRIPTION:100px;Creates a Huygens source. If the Huygens source 'label' already exists, its properties are modified. ====huygens_surface==== SYNTAX: huygens_surface({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2, {{ArgTypeAny}} xSamples, {{ArgTypeAny}} ySamples, {{ArgTypeAny}} zSamples) EXAMPLE: ''huygens_surface(" | horn_design_bHS_1",-10,-10,-10,10,10,10,40,40,40)'' DESCRIPTION: Creates a Huygens surface observable. If the observable 'label' already exists, its properties are modified. ====huygens_surface_grid==== SYNTAX: huygens_surface_grid(D0_dB{{ArgTypeString}} label,a_lambda{{ArgTypeAny}} x1,b_lambda{{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2)| styleEXAMPLE: ''huygens_surface_grid("HS_1",-10,-10,-10,10,10,10)'' DESCRIPTION: Creates a Huygens surface observable in [[EM.Tempo]]. If the observable 'label' already exists, its properties are modified. ====hyperbola==== SYNTAX: hyperbola({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} diam_x, {{ArgTypeAny}} diam_y, {{ArgTypeAny}} axial_length, {{ArgTypeAny}} half_only) EXAMPLE: ''hyperbola("widthHyperbola _1",0,0,0,50,40,20,0)'' DESCRIPTION:150px;Draws a hyperbola object in the project workspace under the currently activated material group node, or modifies the hyperbola named 'label' if it already exists. If the Boolean parameter " | EMAG Python functionhalf_only" is 1, only half of the hyperbola will be drawn.  | style====impedance_surface_group==== SYNTAX: impedance_surface_group({{ArgTypeString}} label, {{ArgTypeAny}} z_real, {{ArgTypeAny}} z_imag) EXAMPLE: ''impedance_surface_group("widthIMP_1",100,-100)'' DESCRIPTION:250px;Creates a impedance_surface group in [[EM.Illumina]]. If the impedance surface group 'label' already exists, the group is activated. ====impenetrable_surface_group==== SYNTAX: impenetrable_surface_group({{ArgTypeString}} label, {{ArgTypeAny}} eps, {{ArgTypeAny}} sigma) EXAMPLE: ''impenetrable_surface_group(" | Returns Impenet_1",2.2,0.0001)'' DESCRIPTION: Creates an impenetrable surface group in [[EM.Terrano]]. If the wavelength-normalized smaller dimension of impenetrable surface group 'label' already exists, the aperture of group is activated. ====import_dxf==== SYNTAX: import_dxf({{ArgTypeString}} file_name) EXAMPLE: ''import_dxf("MyDXFModel.DXF")'' DESCRIPTION: Imports an optimal pyramidal horn antenna external DXF model file to the project workspace. If the file path is not specified, the current project folder is assumed as the path. | style====import_igs==== SYNTAX: import_igs({{ArgTypeString}} file_name) EXAMPLE: ''import_igs("widthMyIGSModel.IGS")'' DESCRIPTION:250pxImports an external IGES model file to the project workspace. If the file path is not specified, the current project folder is assumed as the path. ====import_py==== SYNTAX: import_py({{ArgTypeString}} file_name) EXAMPLE: ''import_py("MyPYModel.PY")'' DESCRIPTION: Imports a Python geometry file to the project workspace. The default path is the Python subfolder under "Documents &rarr;EMAG" | D0_dB. ====import_stl==== SYNTAX: directivity dimport_stl({{ArgTypeString}} file_name) EXAMPLE: ''import_stl("MySTLModel.STL")'' DESCRIPTION: Imports an external STL model file to the project workspace. If the file path is not specified, a_lambdathe current project folder is assumed as the path. ====import_stp==== SYNTAX: wavelength-normalized larger dimension of import_stp({{ArgTypeString}} file_name) EXAMPLE: ''import_stp("MySTPModel.STP")'' DESCRIPTION: Imports an external STEP model file to the feed waveguideproject workspace. If the file path is not specified, b_lambdathe current project folder is assumed as the path. ====inductance==== SYNTAX: wavelengthinductance({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2, {{ArgTypeAny}} x3, {{ArgTypeAny}} y3, {{ArgTypeAny}} z3, {{ArgTypeAny}} x4, {{ArgTypeAny}} y4, {{ArgTypeAny}} z4) EXAMPLE: ''inductance("FI_1",0,0,-normalized smaller dimension of 10,10,0,10,2.5,-2.5,0,7.5,2.5,0)'' DESCRIPTION: Creates a inductance integral observable in [[EM.Ferma]]. If the feed waveguide observable 'label' already exists, its properties are modified.|-| style====inductor==== SYNTAX: inductor({{ArgTypeString}} label, {{ArgTypeAny}} line_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} inductance_nH) EXAMPLE: ''inductor("widthCap_1","Line_1",25,10)'' DESCRIPTION:100px;Creates a inductor in [[EM.Tempo]]. If the inductor 'label' already exists, its properties are modified. ====intersect==== SYNTAX: intersect({{ArgTypeString}} label, {{ArgTypeString}} object_1, {{ArgTypeString}} object_2) EXAMPLE: ''intersect(" | horn_design_lIntersection_Object","Rect_Strip1","Rect_Strip2")'' DESCRIPTION: Creates a Boolean object named 'label' by intersecting object_1 and object_2. An error will be thrown if a Boolean object named 'label' already exists. ====line==== SYNTAX: line(D0_dB{{ArgTypeString}} label,a_lambda{{ArgTypeAny}} x0,b_lambda{{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} length[, {{ArgTypeAny}} dir])| styleEXAMPLE: ''line("my_line",0,0,0,100,"x")'' DESCRIPTION: Draws a Line object in the project workspace under the currently activated material group node, or modifies the line named 'label' if it already exists. Without the argument "dir", a vertical line is drawn by default.  ====loft==== SYNTAX: loft({{ArgTypeString}} label, {{ArgTypeString}} object, {{ArgTypeAny}} loft_height, {{ArgTypeAny}} cap_base) EXAMPLE: ''loft("widthLoft_1","Rect_Strip1",50)'' DESCRIPTION:150px; Creates or modifies a loft object from a specified object by the specified height. If modifying an existing loft object, the pre-existing primitive is used. This command can only loft objects that have a single face and will loft along the face's normal. ====lumped_src==== SYNTAX: lumped_src({{ArgTypeString}} label, {{ArgTypeAny}} line_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} polarity[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]) EXAMPLE: ''lumped_src(" | EMAG Python LS_1","Line_1",50,0)'' DESCRIPTION: Creates a lumped source in [[EM.Tempo]]. If the lumped source 'label' already exists, its properties are modified. ====magnet_group==== SYNTAX: magnet_group({{ArgTypeString}} label, {{ArgTypeAny}} mu, {{ArgTypeAny}} Mx, {{ArgTypeAny}} My, {{ArgTypeAny}} Mz) EXAMPLE: ''magnet_group("Magnet_1",1,0,0,100)'' DESCRIPTION: Creates a permanent magnet source group in [[EM.Ferma]]. If the magnet group 'label' already exists, the group is activated. ====mcos==== SYNTAX: mcos({{ArgTypeReal}} x, {{ArgTypeReal}} r) EXAMPLE: ''mcos(0.5,2)'' DESCRIPTION: Computes and returns the super-quadratic cosine functionof order r. | style====mean==== SYNTAX: mean({{ArgTypeReal}} x, {{ArgTypeReal}} y) EXAMPLE: ''mean(1,2)'' DESCRIPTION: Computes and returns the arithmetic mean of x and y: 0.5*(x+y). ====merge_curve==== SYNTAX: merge_curve({{ArgTypeString}} object_1, {{ArgTypeString}} object_2) EXAMPLE: ''merge_curve("Curve_1","Curve_2")'' DESCRIPTION: Merges two specified curve objects into a single curve. ====mesh==== SYNTAX: mesh() DESCRIPTION: Generates and displays the mesh of the physical structure. ====microstrip_design==== SYNTAX: microstrip_design({{ArgTypeReal}} z0, {{ArgTypeReal}} er) EXAMPLE: ''microstrip_design(50,2.2)'' DESCRIPTION: Computes and returns the width-to-height ratio of a microstrip transmission line with characteristic impedance z0 in Ohms and substrate relative permittivity er. ====microstrip_eps_eff==== SYNTAX:250px;" | Returns microstrip_eps_eff({{ArgTypeReal}} w, {{ArgTypeReal}} h, {{ArgTypeReal}} er) EXAMPLE: ''microstrip_eps_eff(2,0.5,2.2)'' DESCRIPTION: Computes and returns the effective permittivity of a microstrip transmission line with width w, substrate height h and substrate relative permittivity er. ====microstrip_lambda_g==== SYNTAX: microstrip_lambda_g({{ArgTypeReal}} w, {{ArgTypeReal}} h, {{ArgTypeReal}} er, {{ArgTypeReal}} freq_hertz) EXAMPLE: ''microstrip_lambda_g(2,0.5,2.2,2e9)'' DESCRIPTION: Computes and returns the guide wavelength(in meters) of a microstrip transmission line with width w, substrate height h and substrate relative permittivity er at an operating frequency of freq_hertz. ====microstrip_src==== SYNTAX: microstrip_src({{ArgTypeString}} label, {{ArgTypeAny}} rect_object, {{ArgTypeAny}} height, {{ArgTypeAny}} edge[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]) EXAMPLE: ''microstrip_src("MS_1","Rect_1",1.5,"+x")'' DESCRIPTION: Creates a microstrip port source in [[EM.Tempo]]. If the microstrip port 'label' already exists, its properties are modified. ====microstrip_z0==== SYNTAX: microstrip_z0({{ArgTypeReal}} w, {{ArgTypeReal}} h, {{ArgTypeReal}} er) EXAMPLE: ''microstrip_z0(2,0.5,2.2)'' DESCRIPTION: Computes and returns the characteristic impedance (in Ohms) of a microstrip transmission line with width w, substrate height h and substrate relative permittivity er. ====microstrip_zoc==== SYNTAX: microstrip_zoc({{ArgTypeReal}} w, {{ArgTypeReal}} l, {{ArgTypeReal}} h, {{ArgTypeReal}} er, {{ArgTypeReal}} freq_hertz) EXAMPLE: ''microstrip_zoc(2,25,0.5,2.2,2e9)'' DESCRIPTION: Computes and returns the input reactance (in Ohms) of an open-normalized circuited microstrip transmission line with width w, length l, substrate height h and substrate relative permittivity er at an operating frequency of freq_hertz. ====microstrip_zsc==== SYNTAX: microstrip_zsc({{ArgTypeReal}} w, {{ArgTypeReal}} l, {{ArgTypeReal}} h, {{ArgTypeReal}} er, {{ArgTypeReal}} freq_hertz) EXAMPLE: ''microstrip_zsc(2,25,0.5,2.2,2e9)'' DESCRIPTION: Computes and returns the input reactance (in Ohms) of a short-circuited microstrip transmission line with width w, length l, substrate height h and substrate relative permittivity er at an optimal pyramidal horn antenna operating frequency of freq_hertz. | style====mirror==== SYNTAX: mirror({{ArgTypeString}} object, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} uX, {{ArgTypeAny}} uY, {{ArgTypeAny}} uZ) EXAMPLE: ''mirror("widthpyramid_1",0,0,0,1,0,0)'' DESCRIPTION:250px;Mirrors an object in a plane defined by the specified point coordinates and specified normal vector components. ====move_to==== SYNTAX: move_to({{ArgTypeString}} object, {{ArgTypeString}} group_node_label[, {{ArgTypeString}} module_name]) EXAMPLE: ''move_to(" NewObj","MyObj",10,10,0)'' DESCRIPTION: Transfers an object from its current material/object group node in the navigation tree to another node or optionally to another [[EM.Cube]] module.  ====msin==== SYNTAX: msin({{ArgTypeReal}} x, {{ArgTypeReal}} r) EXAMPLE: ''msin(0.5,2)'' DESCRIPTION: Computes and returns the super-quadratic sine function of order r. ====nurbs_curve==== SYNTAX: nurbs_curve({{ArgTypeString}} label, {{ArgType| D0_dB3x1 Python tuple}} p0, {{ArgType| 3x1 Python tuple}} p1, ... {{ArgType| 3x1 Python tuple}} pn) EXAMPLE: directivity d''nurbs_curve("nc_1", a_lambda(0,0,0),(1,0,0),(1,0,0))'' DESCRIPTION: wavelengthCreates or modifies a NURBS Curve object in the project workspace. Each point is represented with a Python tuple type. The curve is closed if p0 is specified again as pn, otherwise, it is open. ====nurbs_strip==== SYNTAX: nurbs_strip({{ArgTypeString}} label, {{ArgType| 3x1 Python tuple}} p0, {{ArgType| 3x1 Python tuple}} p1, ... {{ArgType| 3x1 Python tuple}} pn) EXAMPLE: ''nurbs_strip("ns_1",(0,0,0),(1,0,0),(1,0,0))'' DESCRIPTION: Creates or modifies a NURBS Strip object in the project workspace. Each point is represented with a Python tuple type. The nurbs_strip function is 'self-normalized larger dimension closing' -- there is no need to supply the first point again at the end of the feed waveguidepoint list. ====ohmic_loss==== SYNTAX: ohmic_loss({{ArgTypeString}} label, b_lambda{{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2) EXAMPLE: wavelength''ohmic_loss("FI_1",-normalized smaller dimension 10,-10,-10,10,10,10)'' DESCRIPTION: Creates an ohmic loss integral observable in [[EM.Ferma]]. If the observable 'label' already exists, its properties are modified. ====parabola==== SYNTAX: parabola({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} focal_length, {{ArgTypeAny}} axial_length, {{ArgTypeAny}} half_only) EXAMPLE: ''parabola("Parabola _1",0,0,0,50,20,0)'' DESCRIPTION: Draws a parabola object in the project workspace under the currently activated material group node, or modifies the parabola named 'label' if it already exists. If the Boolean parameter "half_only" is 1, only half of the feed waveguide parabola will be drawn. |====param_curve==== SYNTAX: param_curve({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} model, {{ArgTypeAny}} orientation, {{ArgTypeAny}} start, {{ArgTypeAny}} stop, {{ArgTypeAny}} step, {{ArgTypeAny}} function[, {{ArgTypeAny}} y(t), {{ArgTypeAny}} z(t)]) EXAMPLE: ''param_curve("Curve_1",0,0,0,"parametric","xy",0,10,0.1,"cos(t)","sin(t)","t")'' DESCRIPTION: Generates a parametric curve in the project workspace under the currently activated material group node, or modifies the parametric curve named 'label' if it already exists. ====param_surface==== SYNTAX: param_surface({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} orientation, {{ArgTypeAny}} start1, {{ArgTypeAny}} stop1, {{ArgTypeAny}} step1, , {{ArgTypeAny}} start2, {{ArgTypeAny}} stop2, {{ArgTypeAny}} step2, {{ArgTypeAny}} function) EXAMPLE: ''param_surface("Surf_1",0,0,0,"xy",0,10,0.1,0,10,0.1,"sin(x)*sin(y)")'' DESCRIPTION: Generates a parametric surface in the project workspace under the currently activated material group node, or modifies the parametric surface named 'label' if it already exists. ====pec_group==== SYNTAX: pec_group({{ArgTypeString}} label) EXAMPLE: ''pec_group("PEC_1")'' DESCRIPTION: Creates a PEC material group in the current module. If the PEC group 'label' already exists, the group is activated. ====pec_via_group==== SYNTAX: pec_via_group({{ArgTypeString}} label, {{ArgTypeAny}} host_layer)

== EM.CubeEXAMPLE: ''pec_via_group("PEC_1",10)''s Python Functions for Geometric Object Creation ==

====box({{ArgTypeString}} DESCRIPTION: Creates an embedded PEC via set group in the current module. If the PEC via group 'label' already exists, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} base_x, {{ArgTypeAny}} base_y, {{ArgTypeAny}} height[, {{ArgTypeAny}} cap_top, {{ArgTypeAny}} cap_bottom])====the group is activated.

DescriptionSYNTAX: Draws a box object in the project workspace under the currently activated material group node, or modifies the box named 'pec_voltage_group({{ArgTypeString}} label' if it already exists., {{ArgTypeAny}} voltage)

====cylinderEXAMPLE: ''pec_voltage_group({{ArgTypeString}} label"PEC_1", {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius, {{ArgTypeAny}} height[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle, {{ArgTypeAny}} cap_top, {{ArgTypeAny}} cap_bottom]10)====''

DESCRIPTION: Creates a fixed-potential PEC object group in the current module. If the PEC group 'label'Example:cylinder("Cylinder_1"already exists,0,0,0,10,100)''the group is activated.

====coneSYNTAX: penetrable_surface_group({{ArgTypeString}} label, {{ArgTypeAny}} x0eps, {{ArgTypeAny}} y0sigma, {{ArgTypeAny}} z0, {{ArgTypeAny}} base_radius, {{ArgTypeAny}} height[, {{ArgTypeAny}} top_radius, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle, {{ArgTypeAny}} cap_top, {{ArgTypeAny}} cap_bottom]thickness)====

EXAMPLE: ''Example:conepenetrable_surface_group("Cone_1Penet_1",0,0,0,30,40,202.2,0.0001,1801)''

DescriptionDESCRIPTION: Draws Creates a cone object penetrable surface group in [[EM.Terrano]]. If the project workspace under the currently activated material penetrable surface group node, or modifies the cone named 'label' if it already exists. The arguments start_angle and end_angle are in degrees and specify a sweep about , the cone's azimuth axisgroup is activated.

====pyramid({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} base_x, {{ArgTypeAny}} base_y, {{ArgTypeAny}} height)penetrable_volume_group====

''ExampleSYNTAX:pyramidpenetrable_volume_group("Pyramid_1"{{ArgTypeString}} label,0{{ArgTypeAny}} eps,0,0,10,10,100{{ArgTypeAny}} sigma)''

DescriptionEXAMPLE: Draws a pyramid object in the project workspace under the currently activated material group node, or modifies the pyramid named 'label' if it already existspenetrable_volume_group("Vol_Penet_1",2.2,0.0001)''

====sphere({{ArgTypeString}} DESCRIPTION: Creates a penetrable volume group in [[EM.Terrano]]. If the penetrable volume group 'label' already exists, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle])====the group is activated.

DescriptionSYNTAX: Draws a sphere pipe_sweep({{ArgTypeString}} object in the project workspace under the currently activated Material Group node, or modifies the sphere named 'label' if it already exists. The arguments start_angle and end_angle are in degrees and specify a sweep about the sphere's azimuth axis.{{ArgTypeAny}} radius)

====ellipsoidEXAMPLE: ''pipe_sweep({{ArgTypeString}} label"Curve_1", {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius_x, {{ArgTypeAny}} radius_y, {{ArgTypeAny}} radius_z[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle]5)====''

''ExampleDESCRIPTION:ellipsoid("Ellipsoid_1",0,0,0,100,100,50,0,360)''Creates a pipe version of a given curve object.

====torusSYNTAX: planewave({{ArgTypeString}} label, {{ArgTypeAny}} x0theta, {{ArgTypeAny}} y0phi, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius_major, {{ArgTypeAny}} radius_minor[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle]polarization)====

'EXAMPLE: 'Example:torus'planewave("Torus_1PW_1",0180,0,0,50,20"tm")''

DescriptionDESCRIPTION: Draws an torus object in Creates a plane wave source. If the project workspace under the currently activated material group node, or modifies the torus named plane wave source 'label' if it already exists. The arguments start_angle and end_angle , its properties are in degrees and specify a sweep about the torus's azimuth axismodified.

====rect_strip({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} side_x, {{ArgTypeAny}} side_y)plot_file====

''ExampleSYNTAX:rect_stripplot_file("my_rectangle",0,0,0,50,20{{ArgTypeString}} filename)''

DescriptionEXAMPLE: Draws a rectangle Strip object in the project workspace under the currently activated material group node, or modifies the rectangle strip object named 'label' if it already existsplot_file("D0.DAT")''

DescriptionSYNTAX: Draws a circle strip object in the project workspace under the currently activated material group node, or modifies the circle strip object named 'pmc_group({{ArgTypeString}} label' if it already exists. The arguments start_angle and end_angle are in degrees and specify a sweep about the circle strip's azimuth axis.)

====radial_stripEXAMPLE: ''pmc_group({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius, {{ArgTypeAny}} base_length, {{ArgTypeAny}} angle"PMC_1")====''

DESCRIPTION: Creates a PMC material group in the current module. If the PMC group 'label'Example:radial_strip("Radial_1"already exists,0,0,0,50,0,90)''the group is activated.

====ellipse_stripSYNTAX: point({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius_x, {{ArgTypeAny}} radius_y[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle])====

EXAMPLE: ''Example:ellipse_strippoint("es_1Point_1",0,0,0,50,010)''

DescriptionDESCRIPTION: Draws a ellipse strip object point in the project workspace under the currently activated material group node, or modifies the ellipse strip object point named 'label' if it already exists. The arguments start_angle and end_angle are in degrees and specify a sweep about the ellipse strip's azimuth axis.

====triangle_strip({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} side1, {{ArgTypeAny}} side2, {{ArgTypeAny}} angle)polygon_reg====

''ExampleSYNTAX:triangle_strippolygon_reg("ts_1"{{ArgTypeString}} label,0{{ArgTypeAny}} x0,0{{ArgTypeAny}} y0,0{{ArgTypeAny}} z0,50{{ArgTypeAny}} radius,100,90{{ArgTypeAny}} n_sides)''

DescriptionEXAMPLE: Draws a triangle strip object in the project workspace under the currently activated material group node''polygon_reg("ts_1",0,0,0,50,100,80, or modifies the triangle strip object named 1)'label' if it already exists.

====taper_strip({{ArgTypeString}} DESCRIPTION: Draws a regular polygon object in the project workspace under the currently activated material group node, or modifies the regular polygon object named 'label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} base_width, {{ArgTypeAny}} top_width, {{ArgTypeAny}} length, {{ArgTypeAny}} is_expo)====' if it already exists.

DescriptionSYNTAX: Draws a taper strip polygonize({{ArgTypeString}} object in the project workspace under the currently activated material group node, or modifies the taper strip object named 'label' if it already exists. If the Boolean parameters "is_expo" is 1, an exponential taper will be drawn. {{ArgTypeAny}} side_length)

====polygon_regEXAMPLE: ''polygonize({{ArgTypeString}} label"Cric_1", {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius, {{ArgTypeAny}} n_sides2)====''

''ExampleDESCRIPTION:polygon_reg("ts_1",0,0,0,50,100,80,1)''Polygonizes the specified surface or curve object by the specified side length. The results is a polystrip or a polyline.

====spiral_stripSYNTAX: polyline({{ArgTypeString}} label, {{ArgTypeAnyArgType| 3x1 Python tuple}} x0p0, {{ArgTypeAnyArgType| 3x1 Python tuple}} y0p1, ... {{ArgTypeAnyArgType| 3x1 Python tuple}} z0, {{ArgTypeAny}} width, {{ArgTypeAny}} radius_inner, {{ArgTypeAny}} radius_outer, {{ArgTypeAny}} nturns, {{ArgTypeAny}} spiral_dir, {{ArgTypeAny}} is_dualpn)====

EXAMPLE: ''Example:spiral_strippolyline("Spiral _1pl_1",(0,0,0),10(1,500,50),(1,0,0))''

DescriptionDESCRIPTION: Draws Creates or modifies a spiral strip PolyLine object in the project workspace under the currently activated material group node, or modifies the spiral strip named 'label' if it already exists. If the Boolean parameter "spiral_dir" Each point is 1, the spiral curve will be drawn counter-clockwiserepresented with a Python tuple type. If the Boolean parameter "is_dual" The poly_line is closed if p0 is 1specified again as pn, a dual-arm spiral curve will be drawnotherwise, it is open.

====polystrip({{ArgTypeString}} label, {{ArgType| 3x1 Python tuple}} p0, {{ArgType| 3x1 Python tuple}} p1, ... {{ArgType| 3x1 Python tuple}} pn)polymesh====

''ExampleSYNTAX:polystrippolymesh("ps_1"{{ArgTypeString}} label,(0{{ArgTypeString}} object,0,0),(1,0,0),(1,0,0){{ArgTypeAny}} edge_length)''

DescriptionEXAMPLE: Creates or modifies a Polystrip object in the project workspace. Each point is represented with a Python tuple type. The poly_strip function is 'self-closing' -- there is no need to supply the first point again at the end of the point list.polymesh("Poly_1","Cric_1",2)''

====nurbs_strip({{ArgTypeString}} label, {{ArgType| 3x1 Python tuple}} p0, {{ArgType| 3x1 Python tuple}} p1, DESCRIPTION: Discretizes the specified solid or surface object by the specified edge length.The results is a polymesh object.. {{ArgType| 3x1 Python tuple}} pn)====

DescriptionSYNTAX: Creates or modifies a NURBS Strip object in the project workspace. Each point is represented with a polystrip({{ArgTypeString}} label, {{ArgType| 3x1 Python tuple type}} p0, {{ArgType| 3x1 Python tuple}} p1, . The nurbs_strip function is 'self-closing' -- there is no need to supply the first point again at the end of the point list.. {{ArgType| 3x1 Python tuple}} pn)

====lineEXAMPLE: ''polystrip({{ArgTypeString}} label"ps_1", {{ArgTypeAny}} x0(0, {{ArgTypeAny}} y00, {{ArgTypeAny}} z00), {{ArgTypeAny}} length[(1, {{ArgTypeAny}} dir]0,0),(1,0,0))====''

''ExampleDESCRIPTION:line("my_line",0,0,0,100,"x")Creates or modifies a Polystrip object in the project workspace. Each point is represented with a Python tuple type. The poly_strip function is 'self-closing'-- there is no need to supply the first point again at the end of the point list.

====circleSYNTAX: port_definition_custom({{ArgTypeString}} label, ({{ArgTypeAnyArgTypeString}} x0port_1_src_1, {{ArgTypeAnyArgTypeString}} y0port_1_src_2, ..., {{ArgTypeAnyArgTypeString}} z0port_1_impedance), ({{ArgTypeAnyArgTypeString}} radiusport_2_src_1, {{ArgTypeAnyArgTypeString}} start_angleport_2_src_2, ..., {{ArgTypeAnyArgTypeString}} end_angleport_2_impedance), ...)====

EXAMPLE: ''Example:circleport_definition_custom("pyramid_1PD_1",0("LS_1",0"LS_2",050),10,10("LS_3","LS_4",10050))''

DescriptionDESCRIPTION: Draws Creates a circular curve object in custom port definition observable. If the project workspace under the currently activated material group node, or modifies the circle named observable 'label' if it already exists. The parameters start_angle and end_angle , its properties are in degreesmodified.

====superquad({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} diam_x, {{ArgTypeAny}} diam_y, {{ArgTypeAny}} order)port_definition_default====

''ExampleSYNTAX:superquadport_definition_default("SuperQuad_1",0,0,0,50,20,4{{ArgTypeString}} label)''

DescriptionEXAMPLE: Draws a super-quadratic curve object in the project workspace under the currently activated material group node, or modifies the super-quadratic curve named 'label' if it already exists. If order = 2, the curve reduces to an ellipse. Higher order make the round edges sharper. An infinite order reduces the curve to a rectangle. port_definition_default("PD_1")''

====parabola({{ArgTypeString}} DESCRIPTION: Creates a default port definition observable. If the observable 'label' already exists, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} focal_length, {{ArgTypeAny}} axial_length, {{ArgTypeAny}} half_only)====its properties are modified.

DescriptionSYNTAX: Draws a parabola object in the project workspace under the currently activated material group node, or modifies the parabola named 'probe_gap_src({{ArgTypeString}} label' if it already exists. If the Boolean parameter "half_only" is 1, only half of the parabola will be drawn. {{ArgTypeAny}} via_object, {{ArgTypeAny}} polarity[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance])

====hyperbolaEXAMPLE: ''probe_gap_src({{ArgTypeString}} label"Probe_1", {{ArgTypeAny}} x0"Via_1", {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} diam_x, {{ArgTypeAny}} diam_y, {{ArgTypeAny}} axial_length, {{ArgTypeAny}} half_only0)====''

DESCRIPTION: Creates a probe gap circuit source in [[EM.Picasso]]. If the probe gap source 'label'Example:hyperbola("Hyperbola _1"already exists,0,0,0,50,40,20,0)''its properties are modified.

====spiral_curveSYNTAX: pyramid({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius_innerbase_x, {{ArgTypeAny}} radius_outerbase_y, {{ArgTypeAny}} nturns, {{ArgTypeAny}} spiral_dir, {{ArgTypeAny}} is_dualheight)====

EXAMPLE: ''Example:spiral_curvepyramid("Spiral _1Pyramid_1",0,0,0,10,5010,5,0,0100)''

DescriptionDESCRIPTION: Draws a spiral curve pyramid object in the project workspace under the currently activated material group node, or modifies the spiral curve pyramid named 'label' if it already exists. If the Boolean parameter "spiral_dir" is 1, the spiral curve will be drawn counter-clockwise. If the Boolean parameter "is_dual" is 1, a dual-arm spiral curve will be drawn.

====helix({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius_inner, {{ArgTypeAny}} radius_outer, {{ArgTypeAny}} nturns, {{ArgTypeAny}} helix_dir)radial_strip====

''ExampleSYNTAX:helixradial_strip("Helix_1"{{ArgTypeString}} label,0{{ArgTypeAny}} x0,0{{ArgTypeAny}} y0,0{{ArgTypeAny}} z0,15{{ArgTypeAny}} radius,15{{ArgTypeAny}} base_length,10,0{{ArgTypeAny}} angle)''

DescriptionEXAMPLE: Draws a helical curve in the project workspace under the currently activated material group node, or modifies the helix named 'label' if it already exists. The parameter radial_strip("radius_innerRadial_1" specifies the helix's radius at the beginning of the helix, and radius_outer specifies the radius at the end of the helix. If the Boolean parameter "helixl_dir" is 10, the helical curve will be drawn counter-clockwise. 0,0,50,0,90)''

====polyline({{ArgTypeString}} DESCRIPTION: Draws a radial strip object in the project workspace under the currently activated material group node, or modifies the radial strip object named 'label, {{ArgType| 3x1 Python tuple}} p0, {{ArgType| 3x1 Python tuple}} p1, ..' if it already exists. {{ArgType| 3x1 Python tuple}} pn)====

DescriptionSYNTAX: Creates or modifies a PolyLine object in the project workspace. Each point is represented with a Python tuple type. The poly_line is closed if p0 is specified again as pnrail_sweep({{ArgTypeString}} rail_object, otherwise, it is open.{{ArgTypeString}} sweep_object)

====nurbs_curveEXAMPLE: ''rail_sweep({{ArgTypeString}} label"Curve_1", {{ArgType| 3x1 Python tuple}} p0, {{ArgType| 3x1 Python tuple}} p1, ... {{ArgType| 3x1 Python tuple}} pn"Curve_2")====''

''ExampleDESCRIPTION:nurbs_curve("nc_1",(0,0,0),(1,0,0),(1,0,0))''Rail-sweeps the specified sweep object along the specified curve object.

====pointSYNTAX: ramp({{ArgTypeStringArgTypeReal}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0x)====

EXAMPLE: ''Example:pointramp("Point_1",0,0,10.5)''

DescriptionDESCRIPTION: Draws a point in Computes and returns the project workspace under the currently activated material group noderamp function: x if x>0, or modifies the point named 'label' 0 if it already existsx<0.

== EM.Cube's Python Functions for Geometric Object Transformation ==rand====

====translate_bySYNTAX: rand({{ArgTypeString}} label, {{ArgTypeReal}} x_dist, {{ArgTypeReal}} y_distx, {{ArgTypeReal}} z_disty)====

EXAMPLE: ''Example:translate_byrand("MyObj",10,100,x1)''

DescriptionDESCRIPTION: Translates Computes and returns a random number between x and y using an object by the specified distances in each directionuniform distribution.

====translate_to({{ArgTypeString}} label, {{ArgTypeReal}} x_dest, {{ArgTypeReal}} y_dest, {{ArgTypeReal}} z_dest)random_group====

''ExampleSYNTAX:translate_torandom_group("MyObj"{{ArgTypeString}} label,20{{ArgTypeString}} key_object,20{{ArgTypeString}} container_object,x2{{ArgTypeAny}} element_count)''

DescriptionEXAMPLE: Translates an object to the specified destination.''random_group("Rand_1","Rect_1","Box_1",100)''

DescriptionSYNTAX: Draws a circular curve object in the scene under the currently activated Material Group node, or modifies a Circle object if Circle 'rcs_bistatic({{ArgTypeString}} label' already exists. The parameters start_angle and end_angle are in degrees., {{ArgTypeAny}} theta_incr, {{ArgTypeAny}} phi_incr[, {{ArgTypeAny}} frequency])

====arrayEXAMPLE: ''rcs_bistatic({{ArgTypeString}} label"RCS_1", {{ArgTypeString}} object1, {{ArgTypeAny}} x_count, {{ArgTypeAny}} y_count, {{ArgTypeAny}} z_count, {{ArgTypeAny}} x_spacing, {{ArgTypeAny}} y_spacing, {{ArgTypeAny}} z_spacing1)====''

DESCRIPTION: Creates a bistatic RCS observable. The frequency can also be optionally specified for [[EM.Tempo]]. If the observable 'label'Example:array("Array_1"already exists,"Rect_Strip_1",4,4,1,"spacing","spacing",0)''its properties are modified.

====explodeSYNTAX: rcs_monostatic({{ArgTypeString}} objectlabel, {{ArgTypeAny}} theta_incr, {{ArgTypeAny}} phi_incr[, {{ArgTypeAny}} frequency])====

EXAMPLE: ''Example:explodercs_monostatic("MyArrayRCS_1",1,1)''

DescriptionDESCRIPTION: Performs an explode operation on Creates a CAD object named monostatic RCS observable. The frequency can also be optionally specified for [[EM.Tempo]]. If the observable 'objectlabel'already exists, its properties are modified.

====subtract({{ArgTypeString}} label, {{ArgTypeString}} object_1, {{ArgTypeString}} object_2)receiver_set====

''ExampleSYNTAX:subtractreceiver_set("Subtract_Object"{{ArgTypeString}} label,"Rect_Strip1"{{ArgTypeAny}} base_point_set[,"Rect_Strip2"{{ArgTypeAny}} pattern_file, {{ArgTypeAny}} rot_x, {{ArgTypeAny}} rot_y, {{ArgTypeAny}} rot_z)''

DescriptionEXAMPLE: Creates a Boolean object named 'label' by subtracting object_2 from object_1receiver_set("TX_1","PT_1","DPL_STD. An error will be thrown if a Boolean object named RAD",0,90,0)'label' already exists.

====union({{ArgTypeString}} DESCRIPTION: Creates a receiver set in [[EM.Terrano]]. If the receiver set 'label' already exists, {{ArgTypeString}} object_1, {{ArgTypeString}} object_2)====its properties are modified.

DescriptionSYNTAX: Creates a Boolean object named 'label' by unioning object_1 and object_2. An error will be thrown if a Boolean object named 'label' already exists.rect({{ArgTypeReal}} x)

====intersectEXAMPLE: ''rect({{ArgTypeString}} label, {{ArgTypeString}} object_1, {{ArgTypeString}} object_20.1)====''

''ExampleDESCRIPTION:intersect("Intersection_Object","Rect_Strip1"Computes and returns the rectangular window function: 1 if x<0.5,"Rect_Strip2")''0 elsewhere.

====extrudeSYNTAX: rect_gap_src({{ArgTypeString}} label, {{ArgTypeStringArgTypeAny}} rect_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} polarity[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} objectphase, {{ArgTypeAny}} heightresistance])====

EXAMPLE: ''Example:extruderect_gap_src("Extrude_ObjectGAP_1","Rect_Strip1Rect_1",500,0)''

DescriptionDESCRIPTION: Creates a strip gap circuit source in [[EM.Picasso]] or modifies an Extrusion object from CAD object 'object'[[EM.Libera]]. If modifying an existing extrusion, the strip gap source 'objectlabel' is ignoredalready exists, and the pre-existing primitive is used. extrude(...) can only extrude objects that have a single face, and will extrude in the direction of the face's normalits properties are modified.

====revolve({{ArgTypeString}} label, {{ArgTypeString}} object, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} uX, {{ArgTypeAny}} uY, {{ArgTypeAny}} uZ, {{ArgTypeAny}} rot_angle)rect_strip====

''ExampleSYNTAX:revolverect_strip("Rev1"{{ArgTypeString}} label,"Line_1"{{ArgTypeAny}} x0,0{{ArgTypeAny}} y0,0{{ArgTypeAny}} z0,0{{ArgTypeAny}} side_x,0,0,1{{ArgTypeAny}} side_y)''

DescriptionEXAMPLE: Creates or modifies a Revolution object called 'label', with a primitive object named 'object'. If modifying an existing Revolution object, 'object' is ignored, and the pre-existing primitive object is used. rect_strip(x0"my_rectangle",y00,z0) specifies the center of revolution0, and (uX0,uY50,uZ20) specifies the revolution axis. rot_angle is in degrees.''

== EM.Cube's Python Functions for Material DESCRIPTION: Draws a rectangle Strip object in the project workspace under the currently activated material group node, or Object Group Creation ==modifies the rectangle strip object named 'label' if it already exists.

====color_group({{ArgTypeString}} label)rename====

''ExampleSYNTAX: color_grouprename("Color_1"{{ArgTypeString}} new_label, {{ArgTypeString}} old_label)''

DescriptionEXAMPLE: Creates a color group in CubeCAD module. If the color group 'label' already existsrename("Box_2", the group is activated."Box_1")''

DescriptionSYNTAX: Creates a PEC material group in the current module. If the PEC group 'resistance({{ArgTypeString}} label' already exists, the group is activated.{{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2, {{ArgTypeAny}} x3, {{ArgTypeAny}} y3, {{ArgTypeAny}} z3, {{ArgTypeAny}} x4, {{ArgTypeAny}} y4, {{ArgTypeAny}} z4)

====pec_voltage_groupEXAMPLE: ''resistance({{ArgTypeString}} label"FI_1", {{ArgTypeAny}} voltage0,0,-10,0,0,10,-10,-10,0,10,10,0)====''

DESCRIPTION: Creates a resistance integral observable in [[EM.Ferma]]. If the observable 'label'Example: pec_voltage_group("PEC_1"already exists,10)''its properties are modified.

====pec_via_groupSYNTAX: resistor({{ArgTypeString}} label, {{ArgTypeAny}} host_layerline_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} resistance)====

EXAMPLE: ''Example: pec_via_groupresistor("PEC_1Res_1",10"Line_1",25,50)''

DescriptionDESCRIPTION: Creates an embedded PEC via set group a resistor in the current module[[EM.Tempo]]. If the PEC via group resistor 'label' already exists, the group is activatedits properties are modified.

====thinwire_group({{ArgTypeString}} label, {{ArgTypeAny}} radius)revolve====

''ExampleSYNTAX: thinwire_grouprevolve("Thinwire_1"{{ArgTypeString}} label,4{{ArgTypeString}} object, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} uX, {{ArgTypeAny}} uY, {{ArgTypeAny}} uZ, {{ArgTypeAny}} rot_angle)''

DescriptionEXAMPLE: Creates a Thinwire material group in the current module. If the thin wire group 'label' already existsrevolve("Rev1", the group is activated."Line_1",0,0,0,0,0,1,360)''

====pmc_groupDESCRIPTION: Creates or modifies a revolution object from a specified object. If modifying an existing revolution object, the pre-existing primitive object is used. ({{ArgTypeString}} labelx0,y0,z0)====specifies the center of revolution, and (uX,uY,uZ) specifies the revolution axis. The revolution angle "rot_angle" is given in degrees.

DescriptionSYNTAX: Creates rosen({{ArgTypeReal}} x, {{ArgTypeReal}} y, {{ArgTypeReal}} a PMC material group in the current module. If the PMC group 'label' already exists, the group is activated.{{ArgTypeReal}} b)

====slot_groupEXAMPLE: ''rosen({{ArgTypeString}} label0.5,0,1,2)====''

''ExampleDESCRIPTION: slot_groupComputes and returns the Rosenbrock function: (a-x)**2 + b*("PMC_1"y-x**2)''**2.

====dielectric_groupSYNTAX: rotate({{ArgTypeString}} labelobject, {{ArgTypeAny}} epsrot_angle_degree, {{ArgTypeAny}} sigmarot_axis_x, {{ArgTypeAny}} murot_axis_y, {{ArgTypeAny}} rhorot_axis_z)====

EXAMPLE: ''Example: dielectric_grouprotate("Dielectric_1pyramid_1","my_eps"45,01,1,0)''

DescriptionDESCRIPTION: Creates Rotates an object about a dielectric material group in line passing through its LCS center and aligned along the current module with specified direction vector (rot_axis) by the specified material properties. If the dielectric group 'label' already exists, the group is activatedangle.

====impenetrable_surface_group({{ArgTypeString}} label, {{ArgTypeAny}} eps, {{ArgTypeAny}} sigma)roughen====

''ExampleSYNTAX: impenetrable_surface_grouproughen("Impenet_1"{{ArgTypeString}} label,2.2{{ArgTypeString}} object,0.0001{{ArgTypeAny}} rms_height, {{ArgTypeAny}} correl_length)''

DescriptionEXAMPLE: Creates an impenetrable surface group in [[EM.Terrano]]. If the impenetrable surface group 'label' already existsroughen("Rect_1", the group is activated.1,5)''

DescriptionSYNTAX: Creates a penetrable surface group in [[EM.Terrano]]. If the penetrable surface group 'label' already exists, the group is activated.run_analysis()

DescriptionSYNTAX: Creates a penetrable volume group in [[EM.Terrano]]. If the penetrable volume group 'label' already exists, the group is activated.save_data({{ArgTypeString}} directory_name)

====terrain_groupEXAMPLE: ''save_data({{ArgTypeString}} label, {{ArgTypeAny}} eps, {{ArgTypeAny}} sigma"Simulation_Data")====''

''ExampleDESCRIPTION: terrain_group("Terrain_1",5Saves [[EM.0,0Cube]]'s output simulation data files under the specified directory.0001)''

====base_point_groupSYNTAX: sawtooth({{ArgTypeStringArgTypeReal}} labelx)====

EXAMPLE: ''Example: base_point_setsawtooth("BP_Set_1"0.5)''

DescriptionDESCRIPTION: Creates a base point set in [[EM.Terrano]]. If Computes and returns the base point set group 'label' already existsascending periodic sawtooth function of period T = 2, the group is activatedoscillating between two values +1 and -1 and having a zero value of at x = 0.

====virtual_group({{ArgTypeString}} label)scale====

''ExampleSYNTAX: virtual_groupscale("VIR_1"{{ArgTypeString}} object, {{ArgTypeAny}} scale_factor)''

DescriptionEXAMPLE: Creates a virtual object group in [[EM.Terrano]]. If the virtual group 'label' already existsscale("pyramid_1", the group is activated.2)''

DescriptionSYNTAX: Creates a impedance_surface group in [[EM.Illumina]]. If the impedance surface group 'label' already exists, the group is activated.select_module({{ArgTypeString}} module_name)

====conductive_sheet_groupEXAMPLE: ''select_module({{ArgTypeString}} label, {{ArgTypeAny}} sigma, {{ArgTypeAny}} thickness"[[EM.Tempo]]")====''

''ExampleDESCRIPTION: conductive_sheet_group("Cond_1",100, 0Selects and sets [[EM.01)'Cube]]'s active module.

====charge_groupSYNTAX: set_bandwidth({{ArgTypeString}} label, {{ArgTypeAny}} densityvalue)====

EXAMPLE: ''Example: charge_groupset_bandwidth("Charge_1",-1e-51e9)''

DescriptionDESCRIPTION: Creates a volume charge source group in Sets [[EM.FermaCube]]. If the charge group 'label' already exists, the group is activateds frequency bandwidth.

====magnet_group({{ArgTypeString}} label, {{ArgTypeAny}} mu, {{ArgTypeAny}} Mx, {{ArgTypeAny}} My, {{ArgTypeAny}} Mz)set_boundary_conditions====

''ExampleSYNTAX: magnet_groupset_boundary_conditions("Magnet_1"{{ArgTypeString}} xn_type,1{{ArgTypeString}} xp_type,0{{ArgTypeString}} yn_type,0{{ArgTypeString}} yp_type,100{{ArgTypeString}} zn_type, {{ArgTypeString}} zp_type)''

DescriptionEXAMPLE: Creates a permanent magnet source group in [[EM.Ferma]]. If the magnet group 'label' already existsset_domain_offset_lambda("pml", the group is activated."pml","pml","pml","pec","pml")''

====volume_current_group({{ArgTypeString}} labelDESCRIPTION: Sets [[EM.Tempo]]'s domain boundary conditions domain offset on the &plusmn;X, {{ArgTypeAny}} Jx&plusmn;Y and &plusmn;Z boundary walls. The options are "pec", {{ArgTypeAny}} Jy, {{ArgTypeAny}} Jz)===="pmc" and "pml".

DescriptionSYNTAX: Creates a volume current source group in [[EM.Ferma]]. If the volume current group 'label' already existsset_domain_offset({{ArgTypeAny}} dxn_offset, the group is activated.{{ArgTypeAny}} dxp_offset, {{ArgTypeAny}} dyn_offset, {{ArgTypeAny}} dyp_offset, {{ArgTypeAny}} dzn_offset, {{ArgTypeAny}} dzp_offset)

====wire_current_groupEXAMPLE: ''set_domain_offset({{ArgTypeString}} label20, {{ArgTypeAny}} current20, {{ArgTypeAny}} wire_radius20,20,0,10)====''

''ExampleDESCRIPTION: wire_current_group("Magnet_1"Sets the domain offset values along the &plusmn;X,1,0&plusmn;Y and &plusmn;Z directions in project units.5)''

====lumped_srcEXAMPLE: ''set_domain_offset_lambda({{ArgTypeString}} label0.1, {{ArgTypeAny}} line_object0.1, {{ArgTypeAny}} offset0.1, {{ArgTypeAny}} polarity[0.1, {{ArgTypeAny}} amplitude0, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]0.25)====''

''ExampleDESCRIPTION: lumped_src("LS_1"Sets the domain offset values along the &plusmn;X,"Line_1",50,0)''&plusmn;Y and &plusmn;Z directions in free-space wavelengths.

====distributed_srcSYNTAX: set_frequency({{ArgTypeString}} label, {{ArgTypeAny}} rect_object, {{ArgTypeAny}} field_dir, {{ArgTypeAny}} profile[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]value)====

EXAMPLE: ''Example: distributed_srcset_frequency("DS_1","Rect_1","+y","uniform"2.4e9)''

DescriptionDESCRIPTION: Creates a distributed source in Sets [[EM.TempoCube]]. If the distributed source 'label' already exists, its properties are modifieds center frequency.

====microstrip_src({{ArgTypeString}} label, {{ArgTypeAny}} rect_object, {{ArgTypeAny}} height, {{ArgTypeAny}} edge[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance])set_lcs_link====

''ExampleSYNTAX: microstrip_srcset_lcs_link("MS_1"{{ArgTypeString}} object,"Rect_1"{{ArgTypeString}} lcs_obj,1.5{{ArgTypeAny}} x_off,"+x"{{ArgTypeAny}} y_off, {{ArgTypeAny}} z_off)''

DescriptionEXAMPLE: Creates a microstrip port source in [[EM.Tempo]]. If the microstrip port 'label' already existsset_lcs_link("pyramid_1", its properties are modified."box_1",50,50,0)''

DescriptionSYNTAX: Creates a CPW port source in [[EM.Tempo]]. If the CPW port 'label' already existsset_periodic({{ArgTypeAny}} is_periodic, its properties are modified.{{ArgTypeAny}} spacingX, {{ArgTypeAny}} spacingY)

====coaxial_srcEXAMPLE: ''set_periodic({{ArgTypeString}} label1, {{ArgTypeAny}} cylinder_object50, {{ArgTypeAny}} outer_radius, {{ArgTypeAny}} edge[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]50)====''

''ExampleDESCRIPTION: coaxial_src("COAX_1","Cyl_1",1Designates the physical structure as periodic and sets the periods along the X and Y directions.5,"+z")''

====waveguide_srcSYNTAX: set_rot({{ArgTypeString}} labelobject, {{ArgTypeAny}} box_objectrot_x, {{ArgTypeAny}} offsetrot_y, {{ArgTypeAny}} is_negative[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]rot_z)====

EXAMPLE: ''Example: waveguide_srcset_rot("WG_1pyramid_1","Box_1"0,500,045)''

DescriptionDESCRIPTION: Creates a waveguide port source in [[EM.Tempo]]. If Sets the waveguide port 'label' already exists, its properties are modifiedthree rotation angles of an object.

====wire_gap_src({{ArgTypeString}} label, {{ArgTypeAny}} line_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} polarity[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance])set_rot_link====

''ExampleSYNTAX: wire_gap_srcset_rot_link("WIG_1"{{ArgTypeString}} object,"Line_1"{{ArgTypeString}} lcs_obj,50{{ArgTypeAny}} x_off_deg,0{{ArgTypeAny}} y_off_deg, {{ArgTypeAny}} z_off_deg)''

DescriptionEXAMPLE: Creates a wire gap circuit source in [[EM.Libera]]. If the wire gap source 'label' already existsset_rot_link("pyramid_1", its properties are modified."box_1",0,0,45)''

====rect_gap_src({{ArgTypeString}} label, {{ArgTypeAny}} rect_object, {{ArgTypeAny}} DESCRIPTION: Links the rotation angles of the LCS of the first object to the rotation angles of the LCS of the second object by the specified angle offset, {{ArgTypeAny}} polarity[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance])====values in degrees along the three axes.

DescriptionSYNTAX: Creates a strip gap circuit source in [[EMset_stackup_order("THS", {{ArgTypeString}} label_1, {{ArgTypeString}} label_2, .Picasso]] or [[EM.Libera]]. If the strip gap source 'label' already exists, its properties are modified.{{ArgTypeString}} label_n, "BHS")

====probe_gap_srcEXAMPLE: ''background_layer({{ArgTypeString}} label"THS", {{ArgTypeAny}} via_object"Top_Layer", {{ArgTypeAny}} polarity["Mid_Layer", {{ArgTypeAny}} amplitude"Bottom_Layer", {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]"BHS")====''

DESCRIPTION: Sets the hierarchy of [[EM.Picasso]]''Example: probe_gap_src(s background layer stackup from top to bottom. The sequence should always start with "Probe_1THS",standing for the top half-space and must end in "Via_1BHS",0)''standing for the bottom half-space. All the intermediate finite-thickness substrate layers must be included and listed in the right order.

====wave_portSYNTAX: set_units({{ArgTypeString}} label, {{ArgTypeAny}} rect_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} is_negative[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance]units)====

EXAMPLE: ''Example: wave_portset_units("WP_1","Rect_1meter",0,0)''

DescriptionDESCRIPTION: Creates a scattering wave port source in Sets [[EM.PicassoCube]] or [[EM.Libera]]. If the wave port 'label' already exists, its properties are modifieds project length units.

====short_dipole({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} length, {{ArgTypeAny}} uX, {{ArgTypeAny}} uY, {{ArgTypeAny}} uZ, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase)sgn====

''ExampleSYNTAX: wave_portsgn("SD_1",0,0,50,3,0,0,1,1,0{{ArgTypeReal}} x)''

DescriptionEXAMPLE: Creates a Hertzian short dipole source. If the short dipole source 'label' already exists, its properties are modifiedsgn(-1.0)''

====planewave({{ArgTypeString}} labelDESCRIPTION: Computes and returns the signum function: 1 if x>0, {{ArgTypeAny}} theta, {{ArgTypeAny}} phi, {{ArgTypeAny}} polarization)====-1 if x<0.

DescriptionSYNTAX: Creates a plane wave source. If the plane wave source 'short_dipole({{ArgTypeString}} label' already exists, its properties are modified.{{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} length, {{ArgTypeAny}} uX, {{ArgTypeAny}} uY, {{ArgTypeAny}} uZ, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase)

====gauss_beamEXAMPLE: ''short_dipole({{ArgTypeString}} label"SD_1", {{ArgTypeAny}} theta0, {{ArgTypeAny}} phi0, {{ArgTypeAny}} polarization50, {{ArgTypeAny}} focus_x3, {{ArgTypeAny}} focus_y0, {{ArgTypeAny}} focus_z0, {{ArgTypeAny}} radius1, {{ArgTypeAny}} p_mode1, {{ArgTypeAny}} q_mode0)====''

DESCRIPTION: Creates a Hertzian short dipole source. If the short dipole source 'label'Example: gauss_beam("PW_1"already exists,180,0,"tm",0,0,0,20,0,0)''its properties are modified.

====huygens_srcSYNTAX: sigmoidnc({{ArgTypeStringArgTypeReal}} labelx, {{ArgTypeAnyArgTypeReal}} filename[, {{ArgTypeAny}} set_lcs, {{ArgTypeAny}} polarization, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} x_rot, {{ArgTypeAny}} y_rot, {{ArgTypeAny}} z_rot]a)====

EXAMPLE: ''Example: huygens_srcsigmoid("HS_1","Huygens_10.HUY"5,1,100,100,0,0,0,0)''

DescriptionDESCRIPTION: Creates a Huygens source. If Computes and returns the Huygens source 'label' already exists, its properties are modifiedsigmoid function of slope a: 2/(1 + exp(-a*x)) - 1.

====transmitter_set({{ArgTypeString}} label, {{ArgTypeAny}} base_point_set[, {{ArgTypeAny}} pattern_file, {{ArgTypeAny}} rot_x, {{ArgTypeAny}} rot_y, {{ArgTypeAny}} rot_z)sinc====

''ExampleSYNTAX: transmitter_setsinc("TX_1","PT_1","DPL_STD.RAD",0,90,0{{ArgTypeReal}} x)''

DescriptionEXAMPLE: Creates a transmitter set in [[EM.Terrano]]. If the transmitter set 'label' already exists, its properties are modifiedsinc(0.5)''

====resistorDESCRIPTION: Computes and returns the sinc function: sin({{ArgTypeString}} label, {{ArgTypeAny}} line_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} resistancepi*x)====/(pi*x).

DescriptionSYNTAX: Creates a resistor in [[EM.Tempo]]. If the resistor 'label' already existsslice({{ArgTypeString}} object, its properties are modified.{{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} uX, {{ArgTypeAny}} uY, {{ArgTypeAny}} uZ)

====capacitorEXAMPLE: ''slice({{ArgTypeString}} label"Rect_1", {{ArgTypeAny}} line_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} capacitance_pF5)====''

''ExampleDESCRIPTION: capacitor("Cap_1","Line_1",25,10)''Slices the specified object into two parts using the specified plane given by the point coordinates and normal vector coordinates.

====inductorSYNTAX: slot_group({{ArgTypeString}} label, {{ArgTypeAny}} line_object, {{ArgTypeAny}} offset, {{ArgTypeAny}} inductance_nH)====

EXAMPLE: ''Example: inductorslot_group("Cap_1","Line_1PMC_1",25,10)''

DescriptionDESCRIPTION: Creates a inductor slot trace group in [[EM.Tempo]]the current module. If the inductor slot trace group 'label' already exists, its properties are modifiedthe group is activated.

====diode({{ArgTypeString}} label, {{ArgTypeAny}} line_object, {{ArgTypeAny}} polarity, {{ArgTypeAny}} is_fA, {{ArgTypeAny}} temperature_K, {{ArgTypeAny}} ideality_factor)solution_plane====

''ExampleSYNTAX: diodesolution_plane("Diode_1"{{ArgTypeString}} label,"Line_1"{{ArgTypeAny}} field_sensor_label,25,0,10,300,1{{ArgTypeAny}} is_quasi)''

DescriptionEXAMPLE: Creates a diode in [[EM.Tempo]]. If the diode 'label' already existssolution_plane("FI_1", its properties are modified."FS_1",1)''

== DESCRIPTION: Creates a 2D solution plane observable in [[EM.CubeFerma]]. If the observable 's Python Functions for Observable Definition ==label' already exists, its properties are modified.

====port_definition_default({{ArgTypeString}} label)sphere====

''ExampleSYNTAX: port_definition_defaultsphere("PD_1"{{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle])''

DescriptionEXAMPLE: Creates a default port definition observable. If the observable 'label' already existssphere("Sphere_1", its properties are modified.0,0,0,10,0,180)''

====port_definition_custom({{ArgTypeString}} DESCRIPTION: Draws a sphere object in the project workspace under the currently activated Material Group node, or modifies the sphere named 'label, ({{ArgTypeString}} port_1_src_1, {{ArgTypeString}} port_1_src_2, ..., {{ArgTypeString}} port_1_impedance), ({{ArgTypeString}} port_2_src_1, {{ArgTypeString}} port_2_src_2, ..., {{ArgTypeString}} port_2_impedance), .' if it already exists.The arguments start_angle and end_angle are in degrees and specify a sweep about the sphere's azimuth axis.)====

DescriptionSYNTAX: Creates a custom port definition observable. If the observable 'spiral_curve({{ArgTypeString}} label' already exists, its properties are modified.{{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius_inner, {{ArgTypeAny}} radius_outer, {{ArgTypeAny}} nturns, {{ArgTypeAny}} spiral_dir, {{ArgTypeAny}} is_dual)

====farfieldEXAMPLE: ''spiral_curve({{ArgTypeString}} label"Spiral _1", {{ArgTypeAny}} theta_incr0, {{ArgTypeAny}} phi_incr0,0,10,50,5,0,0)====''

DESCRIPTION: Draws a spiral curve object in the project workspace under the currently activated material group node, or modifies the spiral curve named 'label'Example: farfield(if it already exists. If the Boolean parameter "FF_1spiral_dir",is 1,the spiral curve will be drawn counter-clockwise. If the Boolean parameter "is_dual" is 1)'', a dual-arm spiral curve will be drawn.

====rcs_bistaticSYNTAX: spiral_strip({{ArgTypeString}} label, {{ArgTypeAny}} theta_incrx0, {{ArgTypeAny}} phi_incry0, {{ArgTypeAny}} z0, {{ArgTypeAny}} width, {{ArgTypeAny}} radius_inner, {{ArgTypeAny}} radius_outer, {{ArgTypeAny}} nturns, {{ArgTypeAny}} spiral_dir, {{ArgTypeAny}} is_dual)====

EXAMPLE: ''Example: rcs_bistaticspiral_strip("RCS_1Spiral _1",10,0,0,10,50,5,0,10)''

DescriptionDESCRIPTION: Creates Draws a bistatic RCS observable. If spiral strip object in the observable project workspace under the currently activated material group node, or modifies the spiral strip named 'label' if it already exists. If the Boolean parameter "spiral_dir" is 1, its properties are modifiedthe spiral curve will be drawn counter-clockwise. If the Boolean parameter "is_dual" is 1, a dual-arm spiral curve will be drawn.

====current_dist({{ArgTypeString}} label)spline_fit====

''ExampleSYNTAX: current_distspline_fit("CD_1"{{ArgTypeString}} object)''

DescriptionEXAMPLE: Creates a current distribution observable. If the observable 'label' already exists, its properties are modified.spline_fit("Poly_1")''

====field_sensor({{ArgTypeString}} labelDESCRIPTION: Applies spline fit transformation on a specified polymesh, {{ArgTypeAny}} dir_coordinate, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} xSize, {{ArgTypeAny}} ySize, {{ArgTypeAny}} zSize, {{ArgTypeAny}} xSamples, {{ArgTypeAny}} ySamples, {{ArgTypeAny}} zSamples)====polyline or polystrip object.

DescriptionSYNTAX: Creates a near-field sensor observable. If the observable 'label' already exists, its properties are modified.spline2({{ArgTypeReal}} x)

====field_sensor_gridEXAMPLE: ''spline2({{ArgTypeString}} label, {{ArgTypeAny}} dir_coordinate, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z01.0)====''

''ExampleDESCRIPTION: field_sensor_grid("FS_1","z",0,0,0)''Computes and returns the quadratic B-spline function.

====field_probeSYNTAX: spline3({{ArgTypeStringArgTypeReal}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0x)====

EXAMPLE: ''Example: field_probespline3("FS_1",0,1.0,50)''

DescriptionDESCRIPTION: Creates a temporal field probe observable in [[EM.Tempo]] or [[EM.Ferma]]. If Computes and returns the observable 'label' already exists, its properties are modifiedcubic B-spline function.

====receiver_set({{ArgTypeString}} label, {{ArgTypeAny}} base_point_set[, {{ArgTypeAny}} pattern_file, {{ArgTypeAny}} rot_x, {{ArgTypeAny}} rot_y, {{ArgTypeAny}} rot_z)sqr_wave====

''ExampleSYNTAX: receiver_setsqr_wave("TX_1","PT_1","DPL_STD.RAD",0,90,0{{ArgTypeReal}} x)''

DescriptionEXAMPLE: Creates a receiver set in [[EM.Terrano]]. If the receiver set 'label' already exists, its properties are modifiedsqr_wave(0.5)''

DESCRIPTION: Computes and returns the periodic square wave function of period T ====huygens_surface({{ArgTypeString}} label2, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2, {{ArgTypeAny}} xSamples, {{ArgTypeAny}} ySamples, {{ArgTypeAny}} zSamples)===oscillating between two values +1 and -1 and having a value of +1 at x =0.

DescriptionSYNTAX: Creates a Huygens surface observable. If the observable 'label' already existssqr2({{ArgTypeReal}} x, its properties are modified.{{ArgTypeReal}} y)

====huygens_surface_gridEXAMPLE: ''sqr2({{ArgTypeString}} label0, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z21)====''

''ExampleDESCRIPTION: huygens_surface_grid("HS_1",-10,-10,-10,10,10,10)''Computes and returns the sum of squares of x and y: x**2 + y**2.

====voltage_integralSYNTAX: sqr2({{ArgTypeStringArgTypeReal}} labelx, {{ArgTypeAnyArgTypeReal}} x1y, {{ArgTypeAnyArgTypeReal}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2z)====

EXAMPLE: ''Example: voltage_integralsqr2("FI_1",0,0,-10,0,01,102)''

DescriptionDESCRIPTION: Creates a voltage integral observable in [[EM.Ferma]]. If Computes and returns the observable 'label' already existssum of squares of x, its properties are modifiedy and z: x**2 + y**2 + z**2.

====current_integral({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2)sqrt2====

''ExampleSYNTAX: current_integralsqrt2("FI_1"{{ArgTypeReal}} x,-10,-10,0,10,10,0{{ArgTypeReal}} y)''

DescriptionEXAMPLE: Creates a current integral observable in [[EM.Ferma]]. If the observable 'label' already existssqrt2(0, its properties are modified.1)''

====conduction_current_integralDESCRIPTION: Computes and returns the radius of the 2D point ({{ArgTypeString}} labelx, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2y): sqrt(x**2 + y**2)====.

DescriptionSYNTAX: Creates a conduction current integral observable in [[EM.Ferma]]. If the observable 'label' already existssqrt3({{ArgTypeReal}} x, its properties are modified.{{ArgTypeReal}} y, {{ArgTypeReal}} z)

====capacitanceEXAMPLE: ''sqrt3({{ArgTypeString}} label0, {{ArgTypeAny}} x11, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2, {{ArgTypeAny}} x3, {{ArgTypeAny}} y3, {{ArgTypeAny}} z3, {{ArgTypeAny}} x4, {{ArgTypeAny}} y4, {{ArgTypeAny}} z42)====''

''ExampleDESCRIPTION: capacitanceComputes and returns the radius of the 3D point ("FI_1"x,-10y,-10,5,10,10,10,0,0,-10,0,0,10z): sqrt(x**2 + y**2 + z**2)''.

====inductanceSYNTAX: step({{ArgTypeStringArgTypeReal}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2, {{ArgTypeAny}} x3, {{ArgTypeAny}} y3, {{ArgTypeAny}} z3, {{ArgTypeAny}} x4, {{ArgTypeAny}} y4, {{ArgTypeAny}} z4x)====

EXAMPLE: ''Example: inductancestep("FI_1",0,0,-10,10,0,10,2.5,-2.5,0,7.5,21.5,0)''

DescriptionDESCRIPTION: Creates a inductance integral observable in [[EM.Ferma]]. If Computes and returns the observable 'label' already existsunit step function: 1 if x>0, its properties are modified0 if x<0.

====resistance({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2, {{ArgTypeAny}} x3, {{ArgTypeAny}} y3, {{ArgTypeAny}} z3, {{ArgTypeAny}} x4, {{ArgTypeAny}} y4, {{ArgTypeAny}} z4)strip_sweep====

''ExampleSYNTAX: resistancestrip_sweep("FI_1"{{ArgTypeString}} object,0,0,-10,0,0,10,-10,-10,0,10,10,0{{ArgTypeAny}} width)''

DescriptionEXAMPLE: Creates a resistance integral observable in [[EM.Ferma]]. If the observable 'label' already existsstrip_sweep("Curve_1", its properties are modified.5)''

DescriptionSYNTAX: Creates an electric flux integral observable in [[EM.Ferma]]. If the observable 'subtract({{ArgTypeString}} label' already exists, its properties are modified.{{ArgTypeString}} object_1, {{ArgTypeString}} object_2)

====flux_magneticEXAMPLE: ''subtract({{ArgTypeString}} label"Subtract_Object", {{ArgTypeAny}} x1"Rect_Strip1", {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2"Rect_Strip2")====''

DESCRIPTION: Creates a Boolean object named 'label'Example: flux_magnetic("FI_1",0,0,-10,10,0,10)by subtracting object_2 from object_1. An error will be thrown if a Boolean object named 'label'already exists.

====energy_electricSYNTAX: superquad({{ArgTypeString}} label, {{ArgTypeAny}} x1x0, {{ArgTypeAny}} y1y0, {{ArgTypeAny}} z1z0, {{ArgTypeAny}} x2diam_x, {{ArgTypeAny}} y2diam_y, {{ArgTypeAny}} z2order)====

EXAMPLE: ''Example: energy_electricsuperquad("FI_1SuperQuad_1",-100,-100,-100,1050,1020,104)''

DescriptionDESCRIPTION: Creates an electric energy integral observable Draws a super-quadratic curve object in [[EM.Ferma]]. If the observable project workspace under the currently activated material group node, or modifies the super-quadratic curve named 'label' if it already exists. If order = 2, its properties are modifiedthe curve reduces to an ellipse. Higher order makes the round edges sharper. An infinite order reduces the curve to a rectangle.

====energy_magnetic({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2)taper_strip====

''ExampleSYNTAX: energy_magnetictaper_strip("FI_1"{{ArgTypeString}} label,-10{{ArgTypeAny}} x0,-10{{ArgTypeAny}} y0,-10{{ArgTypeAny}} z0,10{{ArgTypeAny}} base_width,10{{ArgTypeAny}} top_width,10{{ArgTypeAny}} length, {{ArgTypeAny}} is_expo)''

DescriptionEXAMPLE: Creates a magnetic energy integral observable in [[EM.Ferma]]. If the observable 'label' already existstaper_strip("ts_1", its properties are modified.0,0,0,50,100,80,1)''

====ohmic_loss({{ArgTypeString}} DESCRIPTION: Draws a taper strip object in the project workspace under the currently activated material group node, or modifies the taper strip object named 'label' if it already exists. If the Boolean parameters "is_expo" is 1, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2)====an exponential taper will be drawn.

DescriptionSYNTAX: Creates an ohmic loss integral observable in [[EM.Ferma]]. If the observable 'terrain_group({{ArgTypeString}} label' already exists, its properties are modified.{{ArgTypeAny}} eps, {{ArgTypeAny}} sigma)

====solution_planeEXAMPLE: ''terrain_group({{ArgTypeString}} label"Terrain_1", {{ArgTypeAny}} field_sensor_label5.0, {{ArgTypeAny}} is_quasi0.0001)====''

DESCRIPTION: Creates an terrain surface group in [[EM.Terrano]]. If the terrain surface group 'label'Example: solution_plane("FI_1"already exists,"FS_1",1)''the group is activated.

====select_moduleEXAMPLE: ''thinwire_group({{ArgTypeString}} module_name"Thinwire_1",4)====''

''ExampleDESCRIPTION: select_module("[[EMCreates a Thinwire material group in the current module.Tempo]]") If the thin wire group 'label'already exists, the group is activated.

====set_unitsSYNTAX: torus({{ArgTypeString}} unitslabel, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} radius_major, {{ArgTypeAny}} radius_minor[, {{ArgTypeAny}} start_angle, {{ArgTypeAny}} end_angle])====

EXAMPLE: ''Example: set_unitstorus("meterTorus_1",0,0,0,50,20)''

DescriptionDESCRIPTION: Sets [[EMDraws an torus object in the project workspace under the currently activated material group node, or modifies the torus named 'label' if it already exists.Cube]]The arguments start_angle and end_angle are in degrees and specify a sweep about the torus's project length unitsazimuth axis.

====set_frequency({{ArgTypeString}} value)translate_by====

''ExampleSYNTAX: set_frequencytranslate_by(2.4e9{{ArgTypeString}} object, {{ArgTypeReal}} x_dist, {{ArgTypeReal}} y_dist, {{ArgTypeReal}} z_dist)''

DescriptionEXAMPLE: Sets [[EM.Cube]]'s center frequency.'translate_by("MyObj",10,10,x)''

DescriptionSYNTAX: Sets [[EM.Cube]]'s frequency bandwidth.translate_to({{ArgTypeString}} object, {{ArgTypeReal}} x_dest, {{ArgTypeReal}} y_dest, {{ArgTypeReal}} z_dest)

====run_analysisEXAMPLE: ''translate_to("MyObj",20,20,x2)====''

DescriptionDESCRIPTION: Runs a simulationTranslates an object to the specified destination.

====set_periodic({{ArgTypeString}} is_periodic, {{ArgTypeString}} spacingX, {{ArgTypeString}} spacingY) transmitter_set====

''ExampleSYNTAX: set_periodictransmitter_set(1{{ArgTypeString}} label,50{{ArgTypeAny}} base_point_set[,50{{ArgTypeAny}} pattern_file, {{ArgTypeAny}} rot_x, {{ArgTypeAny}} rot_y, {{ArgTypeAny}} rot_z)''

DescriptionEXAMPLE: Designates the physical structure as periodic and sets the periods along the X and Y directions''transmitter_set("TX_1","PT_1","DPL_STD.RAD",0,90,0)''

====emtempo_mesh_settingsSYNTAX: tri({{ArgTypeStringArgTypeReal}} cells_per_lambda, {{ArgTypeString}} ratio_contour, {{ArgTypeString}} ratio_thin, {{ArgTypeString}} ratio_absx)====

EXAMPLE: ''Example: emtempo_mesh_settingstri(30,0.1,0.1,0.02)''

DescriptionDESCRIPTION: Sets Computes and returns the parameters of [[EM.Tempo]]'s adaptive mesh generatortriangular window function: 1-|x| if x<1, 0 elsewhere.

====emillumina_mesh_settings({{ArgTypeString}} cells_per_lambda)tri_wave====

''ExampleSYNTAX: emillumina_mesh_settingstri_wave(30{{ArgTypeReal}} x)''

DescriptionEXAMPLE: Sets the parameters of [[EM.Illumina]]'s mesh generator'tri_wave(0.5)''

DESCRIPTION: Computes and returns the periodic triangular wave function of period T ====empicasso_mesh_settings({{ArgTypeString}} cells_per_lambda2, {{ArgTypeString}} ratio_contour, {{ArgTypeString}} ratio_thin, {{ArgTypeString}} ratio_abs)===oscillating between two values +1 and -1 and having a value of +1 at x =0.

DescriptionSYNTAX: Sets the parameters of [[EM.Picasso]]'s planar hybrid mesh generator.triangle_strip({{ArgTypeString}} label, {{ArgTypeAny}} x0, {{ArgTypeAny}} y0, {{ArgTypeAny}} z0, {{ArgTypeAny}} side1, {{ArgTypeAny}} side2, {{ArgTypeAny}} angle)

====emlibera_mesh_settingsEXAMPLE: ''triangle_strip({{ArgTypeString}} cells_per_lambda"ts_1",0,0,0,50,100,90)====''

''ExampleDESCRIPTION: emlibera_mesh_settings(30)Draws a triangle strip object in the project workspace under the currently activated material group node, or modifies the triangle strip object named 'label'if it already exists.

====emferma_mesh_settingsSYNTAX: union({{ArgTypeString}} cell_size_xlabel, {{ArgTypeString}} cell_size_yobject_1, {{ArgTypeString}} cell_size_zobject_2)====

EXAMPLE: ''Example: emferma_mesh_settingsunion(0.5"Union_Object",0.5"Rect_Strip1",0.5"Rect_Strip2")''

DescriptionDESCRIPTION: Sets the parameters of [[EMCreates a Boolean object named 'label' by unioning object_1 and object_2.Ferma]] An error will be thrown if a Boolean object named 'label's fixed-cell mesh generatoralready exists.

====emterrano_mesh_settings({{ArgTypeString}} edge_length, {{ArgTypeString}} angle_tol)virtual_group====

''ExampleSYNTAX: emterrano_mesh_settingsvirtual_group(5,10{{ArgTypeString}} label)''

DescriptionEXAMPLE: Sets the parameters of [[EM.Terrano]]'s facet mesh generator.'virtual_group("VIR_1")''

====cubecad_mesh_settings({{ArgTypeString}} edge_lengthDESCRIPTION: Creates a virtual object group in [[EM.Terrano]]. If the virtual group 'label' already exists, {{ArgTypeString}} angle_tol)====the group is activated.

DescriptionSYNTAX: Sets the parameters of CubeCAD's mesh generator.voltage_integral({{ArgTypeString}} label, {{ArgTypeAny}} x1, {{ArgTypeAny}} y1, {{ArgTypeAny}} z1, {{ArgTypeAny}} x2, {{ArgTypeAny}} y2, {{ArgTypeAny}} z2)

====emtempo_engine_settingsEXAMPLE: ''voltage_integral({{ArgTypeString}} engine"FI_1", {{ArgTypeString}} power_threshhold0, {{ArgTypeString}} max_timesteps0,-10,0,0,10)====''

DESCRIPTION: Creates a voltage integral observable in [[EM.Ferma]]. If the observable 'label'Example: emtempo_engine_settings("single-precision"already exists,-50,20000)''its properties are modified.

====emterrano_engine_settingsSYNTAX: volume_current_group({{ArgTypeString}} bounce_countlabel, {{ArgTypeStringArgTypeAny}} do_edge_diffractionJx, {{ArgTypeStringArgTypeAny}} angular_resolutionJy, {{ArgTypeStringArgTypeAny}} ray_threshholdJz)====

EXAMPLE: ''Example: emterrano_engine_settingsvolume_current_group(5"Magnet_1",10,10,-1001e6)''

DescriptionDESCRIPTION: Sets the parameters of Creates a volume current source group in [[EM.TerranoFerma]]. If the volume current group 's SBR simulation enginelabel' already exists, the group is activated.

====empicasso_engine_settings({{ArgTypeString}} matrix_solver, {{ArgTypeString}} error_tol, {{ArgTypeString}} max_iterations)wave_port====

''ExampleSYNTAX: empicasso_engine_settingswave_port("bicg"{{ArgTypeString}} label,1e-3{{ArgTypeAny}} rect_object,1000{{ArgTypeAny}} offset, {{ArgTypeAny}} is_negative[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} resistance])''

DescriptionEXAMPLE: Sets the parameters of [[EM.Picasso]]'s planar MoM simulation engine.'wave_port("WP_1","Rect_1",0,0)''

====emillumina_engine_settings({{ArgTypeString}} engineDESCRIPTION: Creates a scattering wave port source in [[EM.Picasso]] or [[EM.Libera]]. If the wave port 'label' already exists, {{ArgTypeString}} is_fixed_iteration, {{ArgTypeString}} error_tol, {{ArgTypeString}} max_iterations)====its properties are modified.

DescriptionSYNTAX: Sets the parameters of [[EM.Illumina]]'s Physical Optics simulation engine.waveguide_design({{ArgTypeReal}} er, {{ArgTypeReal}} freq_hertz)

====emferma_engine_settingsEXAMPLE: ''waveguide_design({{ArgTypeString}} matrix_solver1.0, {{ArgTypeString}} error_tol, {{ArgTypeString}} max_iterations2e9)====''

''ExampleDESCRIPTION: emferma_engine_settingsComputes and returns the minimum larger dimension ("bicg-stab",1e-3,100in meters)''of the cross section of a hollow rectangular waveguide above cutoff with a material filling of relative permittivity er at an operating frequency of freq_hertz.

====emlibera_engine_settings_wmomSYNTAX: waveguide_src({{ArgTypeString}} matrix_solverlabel, {{ArgTypeStringArgTypeAny}} error_tolbox_object, {{ArgTypeStringArgTypeAny}} offset, {{ArgTypeAny}} is_negative[, {{ArgTypeAny}} amplitude, {{ArgTypeAny}} phase, {{ArgTypeAny}} max_iterationsresistance])====

EXAMPLE: ''Example: emlibera_engine_settings_wmomwaveguide_src("bicgWG_1","Box_1",1e-350,10000)''

DescriptionDESCRIPTION: Sets the parameters of Creates a waveguide port source in [[EM.LiberaTempo]]. If the waveguide port 'label's wire MoM simulation enginesalready exists, its properties are modified.

====emlibera_engine_settings_smom({{ArgTypeString}} matrix_solver, {{ArgTypeString}} error_tol, {{ArgTypeString}} max_iterations, {{ArgTypeString}} ncpus, {{ArgTypeString}} formulation, {{ArgTypeString}} alpha)wire_current_group====

''ExampleSYNTAX: emlibera_engine_settings_smomwire_current_group("bicg"{{ArgTypeString}} label,1e-3{{ArgTypeAny}} current,1000,4,"efie",0.4{{ArgTypeAny}} wire_radius)''

DescriptionEXAMPLE: Sets the parameters of [[EM.Libera]]'s surface MoM simulation engines'wire_current_group("Magnet_1",1,0.5)''

{"global_ground",emag_set_ground,METH_VARARGS,"global_groundEXAMPLE: ''wire_gap_src(ground_on,eps,sigma) -- Set or unset global ground in [[EM.Terrano]]."}, {"get_domain_extentWIG_1",emag_dom_getextents,METH_VARARGS,"get_domain_extent(coordinate) -- Get the specified extent of the domain box.Line_1"}, {"set_domain_offset"50,emag_dom_offset,METH_VARARGS,"set_domain_offset(dxn_offset,dxp_offset,dyn_offset,dyp_offset,dzn_offset,dzp_offset0) -- Set the offset values of the domain box in project units in all six directions."}, {"set_domain_offset_lambda",emag_dom_offset_lambda,METH_VARARGS,"set_domain_offset_lambda(dxn_offset,dxp_offset,dyn_offset,dyp_offset,dzn_offset,dzp_offset) -- Set the offset values of the domain box in wavelengths in all six directions."}, {"set_boundary_conditions",emag_set_bc,METH_VARARGS,"set_boundary_conditions(xn_type,xp_type,yn_type,yp_type,zn_type,zp_type) -- Set the boundary conditions on all the six walls of the domain box."},''

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