202 lines
6.8 KiB
Python
202 lines
6.8 KiB
Python
# -*- coding: utf-8 -*-
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"""
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Bent Patch Antenna Tutorial
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Tested with
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- python 3.4
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- openEMS v0.0.33+
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(C) 2016 Thorsten Liebig <thorsten.liebig@gmx.de>
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"""
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### Import Libraries
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import os, tempfile
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from pylab import *
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from mpl_toolkits.mplot3d import Axes3D
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from CSXCAD import CSXCAD
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from openEMS.openEMS import openEMS
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from openEMS.physical_constants import *
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### Setup the simulation
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Sim_Path = os.path.join(tempfile.gettempdir(), 'Bent_Patch')
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post_proc_only = False
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unit = 1e-3 # all length in mm
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f0 = 2.4e9 # center frequency, frequency of interest!
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lambda0 = round(C0/f0/unit) # wavelength in mm
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fc = 0.5e9 # 20 dB corner frequency
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# patch width in alpha-direction
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patch_width = 32 # resonant length in alpha-direction
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patch_radius = 50 # radius
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patch_length = 40 # patch length in z-direction
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#substrate setup
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substrate_epsR = 3.38
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substrate_kappa = 1e-3 * 2*pi*2.45e9 * EPS0*substrate_epsR
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substrate_width = 80
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substrate_length = 90
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substrate_thickness = 1.524
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substrate_cells = 4
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#setup feeding
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feed_pos = -5.5 #feeding position in x-direction
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feed_width = 2 #feeding port width
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feed_R = 50 #feed resistance
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# size of the simulation box
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SimBox_rad = 2*100
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SimBox_height = 1.5*200
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### Setup FDTD parameter & excitation function
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FDTD = openEMS(CoordSystem=1, EndCriteria=1e-4) # init a cylindrical FDTD
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f0 = 2e9 # center frequency
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fc = 1e9 # 20 dB corner frequency
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FDTD.SetGaussExcite(f0, fc)
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FDTD.SetBoundaryCond(['MUR', 'MUR', 'MUR', 'MUR', 'MUR', 'MUR']) # boundary conditions
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### Setup the Geometry & Mesh
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# init a cylindrical mesh
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CSX = CSXCAD.ContinuousStructure(CoordSystem=1)
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FDTD.SetCSX(CSX)
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mesh = CSX.GetGrid()
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mesh.SetDeltaUnit(unit)
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### Setup the geometry using cylindrical coordinates
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# calculate some width as an angle in radiant
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patch_ang_width = patch_width/(patch_radius+substrate_thickness)
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substr_ang_width = substrate_width/patch_radius
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feed_angle = feed_pos/patch_radius
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# create patch
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patch = CSX.AddMetal('patch') # create a perfect electric conductor (PEC)
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start = [patch_radius+substrate_thickness, -patch_ang_width/2, -patch_length/2 ]
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stop = [patch_radius+substrate_thickness, patch_ang_width/2, patch_length/2 ]
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patch.AddBox(priority=10, start=start, stop=stop) # add a box-primitive to the metal property 'patch'
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FDTD.AddEdges2Grid(dirs='all', properties=patch)
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# create substrate
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substrate = CSX.AddMaterial('substrate', epsilon=substrate_epsR, kappa=substrate_kappa )
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start = [patch_radius , -substr_ang_width/2, -substrate_length/2]
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stop = [patch_radius+substrate_thickness, substr_ang_width/2, substrate_length/2]
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substrate.AddBox(start=start, stop=stop)
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FDTD.AddEdges2Grid(dirs='all', properties=substrate)
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# save current density oon the patch
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jt_patch = CSX.AddDump('Jt_patch', dump_type=3, file_type=1)
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start = [patch_radius+substrate_thickness, -substr_ang_width/2, -substrate_length/2]
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stop = [patch_radius+substrate_thickness, +substr_ang_width/2, substrate_length/2]
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jt_patch.AddBox(start=start, stop=stop)
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# create ground
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gnd = CSX.AddMetal('gnd') # create a perfect electric conductor (PEC)
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start = [patch_radius, -substr_ang_width/2, -substrate_length/2]
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stop = [patch_radius, +substr_ang_width/2, +substrate_length/2]
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gnd.AddBox(priority=10, start=start, stop=stop)
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FDTD.AddEdges2Grid(dirs='all', properties=gnd)
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# apply the excitation & resist as a current source
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start = [patch_radius , feed_angle, 0]
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stop = [patch_radius+substrate_thickness, feed_angle, 0]
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port = FDTD.AddLumpedPort(1 ,feed_R, start, stop, 'r', 1.0, priority=50, edges2grid='all')
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### Finalize the Mesh
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# add the simulation domain size
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mesh.AddLine('r', patch_radius+np.array([-20, SimBox_rad]))
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mesh.AddLine('a', [-0.75*pi, 0.75*pi])
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mesh.AddLine('z', [-SimBox_height/2, SimBox_height/2])
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# add some lines for the substrate
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mesh.AddLine('r', patch_radius+np.linspace(0,substrate_thickness,substrate_cells))
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# generate a smooth mesh with max. cell size: lambda_min / 20
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max_res = C0 / (f0+fc) / unit / 20
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max_ang = max_res/(SimBox_rad+patch_radius) # max res in radiant
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mesh.SmoothMeshLines(0, max_res, 1.4)
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mesh.SmoothMeshLines(1, max_ang, 1.4)
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mesh.SmoothMeshLines(2, max_res, 1.4)
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## Add the nf2ff recording box
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nf2ff = FDTD.CreateNF2FFBox()
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### Run the simulation
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if 0: # debugging only
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CSX_file = os.path.join(Sim_Path, 'bent_patch.xml')
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if not os.path.exists(Sim_Path):
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os.mkdir(Sim_Path)
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CSX.Write2XML(CSX_file)
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os.system(r'AppCSXCAD "{}"'.format(CSX_file))
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if not post_proc_only:
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FDTD.Run(Sim_Path, verbose=3, cleanup=True)
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### Postprocessing & plotting
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f = np.linspace(max(1e9,f0-fc),f0+fc,401)
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port.CalcPort(Sim_Path, f)
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Zin = port.uf_tot / port.if_tot
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s11 = port.uf_ref/port.uf_inc
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s11_dB = 20.0*np.log10(np.abs(s11))
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figure()
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plot(f/1e9, s11_dB)
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grid()
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ylabel('s11 (dB)')
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xlabel('frequency (GHz)')
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P_in = 0.5*np.real(port.uf_tot * np.conj(port.if_tot)) # antenna feed power
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# plot feed point impedance
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figure()
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plot( f/1e6, real(Zin), 'k-', linewidth=2, label=r'$\Re(Z_{in})$' )
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grid()
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plot( f/1e6, imag(Zin), 'r--', linewidth=2, label=r'$\Im(Z_{in})$' )
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title( 'feed point impedance' )
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xlabel( 'frequency (MHz)' )
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ylabel( 'impedance ($\Omega$)' )
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legend( )
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idx = np.where((s11_dB<-10) & (s11_dB==np.min(s11_dB)))[0]
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if not len(idx)==1:
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print('No resonance frequency found for far-field calulation')
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else:
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f_res = f[idx[0]]
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theta = np.arange(-180.0, 180.0, 2.0)
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print("Calculate NF2FF")
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nf2ff_res_phi0 = nf2ff.CalcNF2FF(Sim_Path, f_res, theta, 0, center=np.array([patch_radius+substrate_thickness, 0, 0])*unit, read_cached=True, outfile='nf2ff_xz.h5')
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figure(figsize=(15, 7))
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ax = subplot(121, polar=True)
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E_norm = 20.0*np.log10(nf2ff_res_phi0.E_norm/np.max(nf2ff_res_phi0.E_norm)) + nf2ff_res_phi0.Dmax
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ax.plot(np.deg2rad(theta), 10**(np.squeeze(E_norm)/20), linewidth=2, label='xz-plane')
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ax.grid(True)
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ax.set_xlabel('theta (deg)')
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ax.set_theta_zero_location('N')
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ax.set_theta_direction(-1)
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ax.legend(loc=3)
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phi = theta
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nf2ff_res_theta90 = nf2ff.CalcNF2FF(Sim_Path, f_res, 90, phi, center=np.array([patch_radius+substrate_thickness, 0, 0])*unit, read_cached=True, outfile='nf2ff_xy.h5')
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ax = subplot(122, polar=True)
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E_norm = 20.0*np.log10(nf2ff_res_theta90.E_norm/np.max(nf2ff_res_theta90.E_norm)) + nf2ff_res_theta90.Dmax
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ax.plot(np.deg2rad(phi), 10**(np.squeeze(E_norm)/20), linewidth=2, label='xy-plane')
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ax.grid(True)
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ax.set_xlabel('phi (deg)')
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suptitle('Bent Patch Anteanna Pattern\nFrequency: {} GHz'.format(f_res/1e9), fontsize=14)
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ax.legend(loc=3)
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print( 'radiated power: Prad = {:.2e} Watt'.format(nf2ff_res_theta90.Prad[0]))
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print( 'directivity: Dmax = {:.1f} ({:.1f} dBi)'.format(nf2ff_res_theta90.Dmax[0], 10*np.log10(nf2ff_res_theta90.Dmax[0])))
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print( 'efficiency: nu_rad = {:.1f} %'.format(100*nf2ff_res_theta90.Prad[0]/real(P_in[idx[0]])))
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show()
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