Zlatko's eBBQ setup tips for Eigenmode simulation

1. Geometry & B.C. definitions: 1A. Define junction rectangles & boundary condition. E.g. rectangle name: juncV. Define the lenght of the junction and junction Lj by a local variable; e.g., junc_len and LJ_V. It is good to keep the junc rectangle on the order of 50 x 100 um. 1B. Define junction line to define current flow direction (polyline). Make it a dmodel objecta and make sure it spans the length of the junction, so use the same variables to define it. Tip: Define an Object coordinate axis before you make the polyline, which is based on the junc rect (e.g., juncV); then define the polyline in the Object CS ( make sure to give the CS a proper name juncV_cs). Now, give the polyline a good name: E.g.,juncV_line.
2. Meshing tips: 4A. Lighly mesh the pads and junc rectangles with roughly 4 initial tets across the smallest dimension.
3. Simulation setup 5A. Advisable, not necessary to used mixed order solutions.

HFSS scripting interface in python

from hfss import get_active_project
proj = get_active_project()
design = proj.new_dm_design("Test")

from hfss import get_active_design
design = get_active_design()

bx = design.set_variable("Box_X", "3mm")
by = design.set_variable("Box_Y", "6mm")
bz = design.set_variable("Box_Z", "1mm")

modeler = design.modeler
modeler.draw_box_center([0,0,0], [bx, by, bz], material="silicon")

setup = design.create_dm_setup(freq_ghz=5)
sweep = setup.insert_sweep(4, 10, count=1000)
setup.analyze()
freqs, (S12, Y11) = sweep.get_network_data("S12,Y11")

fields = setup.get_fields()
Mag_E_Sq = fields.Mag_E ** 2
Surface_E = Mag_E_Sq.integrate_surf("Object Name")
print Surface_E.evaluate()

• name: str
• nonmodel: bool
• color: (int, int, int) each in [0...255]
• transparency: float in [0, 1]
• material: str (matching existing material name)

If your script terminates improperly, this can happen. pyHFSS tries to catch termination events and handle them. Your safety should be guaranteed however, if you call hfss.release() when you have finished

pint - pip install pint pandas - conda install pandas

calculate_H:  
    True: 1 junction method of Pj calculation based on U_H-U_E global. 
    
Pj_from_current:
    Multi-junction calculation of energy participation ratio matrix based on <I_J>. Current is integrated average of J_surf by default: (zkm 3/29/16)
    Will calculate the Pj matrix for the selected modes for the given junctions junc_rect array & length of juuncs
    
    junc_rect = ['junc_rect1', 'junc_rect2'] name of junc rectangles to integrate H over
    junc_len = [0.0001]   specify in SI units; i.e., meters
    junc_LJ_var_name = ['LJ1', 'LJ2']
    pJ_method = 'J_surf_mag'   - currently only 1 implemented - takes the avg. Jsurf over the rect. Make sure you have seeded lots of tets here. i recommend starting with 4 across smallest dimension.

    Assumptions:
        Low dissipation (high-Q). 
        Right now, we assume that there are no lumped capcitors to simply calculations. Not required. 
        We assume that there are only lumped inductors, so that U_tot = U_E+U_H+U_L    and U_C =0, so that U_tot = 2*U_E;
    Results in:
        self.PJ_multi_sol - a Pandas DataFrame of all the information

Other parameters:
    seams = ['seam1', 'seam2']  (seams needs to be a list of strings)
    variations = ['0', '1']