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@@ -1,45 +1,75 @@
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+import math
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+
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+XLIM = [-1.1, 1.1]
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+YLIM = [-1.1, 1.1]
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+
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+
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+def round_up(x, n=7):
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+ if x == 0:
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+ return 0
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+ deg = math.floor(math.log(abs(x), 10))
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+ return (10 ** deg) * round(x / (10 ** deg), n - 1)
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+
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+
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+def circle(ax, x, y, radius, color='#1946BA'):
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+ from matplotlib.patches import Ellipse
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+ circle = Ellipse((x, y), radius * 2, radius * 2, clip_on=False,
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+ zorder=2, linewidth=2, edgecolor=color, facecolor=(0, 0, 0, .0125))
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+ ax.add_artist(circle)
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+
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+
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import streamlit as st
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import matplotlib.pyplot as plt
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import numpy as np
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import math
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-def plot_data(r,i, g):
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- # unit circle
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- unit_circle_x = []
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- unit_circle_y = []
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- for x in np.arange(-1, 1, 0.01):
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- unit_circle_x.append(x)
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- unit_circle_y.append((1-x**2)**0.5)
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-
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- unit_circle_x.append(1)
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- unit_circle_y.append(0)
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-
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- for x in np.arange(-1, 1, 0.01)[::-1]:
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- unit_circle_x.append(x)
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- unit_circle_y.append(-(1-x**2)**0.5)
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- fig, ax = plt.subplots()
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- ax.plot(unit_circle_x, unit_circle_y)
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+def plot_data(r, i, g):
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+ fig = plt.figure(figsize=(10, 10))
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+ ax = fig.add_subplot()
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+ ax.set_xlim(XLIM)
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+ ax.set_ylim(YLIM)
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+ major_ticks = np.arange(-1.0, 1.1, 0.25)
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+ minor_ticks = np.arange(-1.1, 1.1, 0.05)
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+ ax.set_xticks(major_ticks)
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+ ax.set_xticks(minor_ticks, minor=True)
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+ ax.set_yticks(major_ticks)
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+ ax.set_yticks(minor_ticks, minor=True)
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+ ax.grid(which='major', color='grey', linewidth=1.5)
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+ ax.grid(which='minor', color='grey', linewidth=0.5, linestyle=':')
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+ plt.xlabel(r'$Re(\Gamma)$', color='gray', fontsize=16, fontname="Cambria")
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+ plt.ylabel('$Im(\Gamma)$', color='gray', fontsize=16, fontname="Cambria")
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+ plt.title('Smith chart', fontsize=24, fontname="Cambria")
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+ # cirlce approximation
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+ radius = abs(g[1] - g[0] / g[2]) / 2
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+ x = ((g[1] + g[0] / g[2]) / 2).real
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+ y = ((g[1] + g[0] / g[2]) / 2).imag
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+ circle(ax, x, y, radius, color='#FF8400')
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#
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-
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- # data
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- ax.plot(r, i, 'b+')
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+ # unit circle
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+ circle(ax, 0, 0, 1)
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#
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- #cirlce approximation
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- # g_c = (np.conj(g[2])*g[1]-g[0])/(np.conj(g[2])-g[2])
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- # g_d = g[0]/g[2]
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- # radius = abs(g_c-g_d)
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- # p=[[],[]]
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- # for alpha in range(0,360):
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- # p[0].append(g_c.real+radius*math.cos(math.radians(alpha)))
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- # p[1].append(g_c.imag+radius*math.sin(math.radians(alpha)))
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- # ax.plot(p[0],p[1])
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+ # data
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+ ax.plot(r, i, '+', ms=10, mew=2, color='#1946BA')
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#
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- ax.grid(True)
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- ax.axis('square')
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- ax.set_yticks(np.arange(-1, 1.2, 0.2))
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- ax.set_yticks(np.arange(-1, 1.2, 0.2))
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+ st.pyplot(fig)
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+
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+
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+def plot_ref_from_f(r, i, f):
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+ fig = plt.figure(figsize=(10, 10))
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+ abs_S = list(math.sqrt(r[n] ** 2 + i[n] ** 2) for n in range(len(r)))
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+ xlim = [min(f)-abs(max(f)-min(f))*0.1, max(f)+abs(max(f)-min(f))*0.1]
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+ ylim = [min(abs_S)-abs(max(abs_S)-min(abs_S))*0.5, max(abs_S)+abs(max(abs_S)-min(abs_S))*0.5]
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+ ax = fig.add_subplot()
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+ ax.set_xlim(xlim)
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+ ax.set_ylim(ylim)
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+ ax.grid(which='major', color='k', linewidth=1)
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+ ax.grid(which='minor', color='grey', linestyle=':', linewidth=0.5)
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+ plt.xlabel(r'$f,\; 1/c$', color='gray', fontsize=16, fontname="Cambria")
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+ plt.ylabel('$|\Gamma|$', color='gray', fontsize=16, fontname="Cambria")
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+ plt.title('Modulus of reflection coefficient from frequency', fontsize=24, fontname="Cambria")
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+ ax.plot(f, abs_S, '+', ms=10, mew=2, color='#1946BA')
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st.pyplot(fig)
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@@ -49,13 +79,12 @@ def run(calc_function):
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if uploaded_file is not None:
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data = uploaded_file.readlines()
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-
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col1, col2 = st.columns(2)
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select_data_format = col1.selectbox('Choose data format from a list',['Frequency, Re(S11), Im(S11)','Frequency, Re(Zin), Im(Zin)'])
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select_separator = col2.selectbox('Choose separator',['" "' ,'","','";"'])
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- select_coupling_losses = st.checkbox('I want to apply corrections for coupling losses (lossy coupling)')
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+ select_coupling_losses = st.checkbox('Apply corrections for coupling losses (lossy coupling)')
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def is_float(element) -> bool:
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try:
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@@ -97,21 +126,23 @@ def run(calc_function):
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validator_status = 'nice'
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# calculate
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- circle_params=[]
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+ circle_params = []
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if len(data) > 0:
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- f,r,i,validator_status = unpack_data(data)
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+ f, r, i, validator_status = unpack_data(data)
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- Q0,sigmaQ0,QL,sigmaQl, circle_params =calc_function(f,r,i)
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+ Q0, sigmaQ0, QL, sigmaQl, circle_params = calc_function(f, r, i)
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+ Q0 = round_up(Q0)
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+ sigmaQ0 = round_up(sigmaQ0)
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+ QL = round_up(QL)
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+ sigmaQl = round_up(sigmaQl)
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st.write("Cable attenuation")
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- st.write(f"Q0 = {Q0} +- {sigmaQ0}, epsilon Q0 ={sigmaQ0/Q0}")
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- st.write(f"QL = {QL} +- {sigmaQl}, epsilon QL ={sigmaQl/QL}")
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-
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+ st.latex(r'Q_0 =' + f'{Q0} \pm {sigmaQ0}, ' + r'\;\;\varepsilon_{Q_0} =' + f'{round_up(sigmaQ0 / Q0)}')
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+ st.latex(r'Q_L =' + f'{QL} \pm {sigmaQl}, ' + r'\;\;\varepsilon_{Q_L} =' + f'{round_up(sigmaQl / QL)}')
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- st.write("Status: " +validator_status)
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+ st.write("Status: " + validator_status)
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if len(data) > 0:
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- f,r,i,validator_status = unpack_data(data)
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+ f, r, i, validator_status = unpack_data(data)
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if validator_status == 'very nice':
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- plot_data(r,i,circle_params)
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-
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-
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+ plot_data(r, i, circle_params)
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+ plot_ref_from_f(r, i, f)
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ricet8ur