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@@ -1,4 +1,4 @@
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-from cmath import atan
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+# from cmath import atan
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import numpy as np
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@@ -14,12 +14,13 @@ def open_file(path):
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re.append(float(temp[1]))
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im.append(float(temp[2]))
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return freq, re, im
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-
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+
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+
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def prepare_data(freq, re, im, fl=None):
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"""the function takes raw data and gives vectors of eq (8)"""
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# finding fl from the point with smallest magnitude if argument not provided
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if fl is None:
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- s = abs(np.array(re) + np.array(im)*1j)
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+ s = abs(np.array(re) + np.array(im) * 1j)
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# frequency of loaded resonance
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fl = freq[list(abs(s)).index(min(abs(s)))]
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@@ -39,6 +40,7 @@ def prepare_data(freq, re, im, fl=None):
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data = np.array([e1, e2, e3, gamma, p], dtype=np.cdouble)
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return data, fl
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+
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def solution(data):
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""" takes projections of equation (8) on vectors e1, e2, e3 and solves the equations.
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It is also gives matrix of equation"""
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@@ -68,27 +70,39 @@ def q_factor(a):
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def recalculation_of_data(data, a, c, d, error=False):
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"""preparation data for the next iteration of solving system"""
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# data = np.array([e1, e2, e3, gamma, p], dtype=complex), t = e1, 1 = e2
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- eps = np.array(a[0]*data[0] + a[1]*data[1] - a[2]*data[0]*data[3] - data[3], dtype=complex)
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+ eps = np.array(a[0] * data[0] + a[1] * data[1] - a[2] * data[0] * data[3] - data[3], dtype=complex)
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# eps is eq(7) line's errors
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- S2 = np.dot(abs(data[4]), abs(eps)*abs(eps)) # the weighted squared sum of errors
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+ S2 = np.dot(abs(data[4]), abs(eps) * abs(eps)) # the weighted squared sum of errors
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sigma2A = [] # the square of standart deviation coefficients a
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- temp = c[0][0]*d[0][0] + c[1][1]*d[1][1] + c[2][2]*d[2][2]
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+ temp = c[0][0] * d[0][0] + c[1][1] * d[1][1] + c[2][2] * d[2][2]
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for i in range(3):
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sigma2A.append(d[i][i] * S2 / temp)
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for i in range(len(data[4])): # recalculation of weight coefficients P
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- data[4][i] = 1/(data[0][i]**2 * sigma2A[0] + sigma2A[1] + data[0][i]**2 * sigma2A[2] * (abs(data[3][i])**2))
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+ data[4][i] = 1 / (
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+ data[0][i] ** 2 * sigma2A[0] + sigma2A[1] + data[0][i] ** 2 * sigma2A[2] * (abs(data[3][i]) ** 2))
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if error:
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return abs(np.array(sigma2A))
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else:
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return data
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+def recalculating(data, a, c, d, n, printing=False):
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+ for i in range(2, n):
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+ data = recalculation_of_data(data, a, c, d)
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+ a, c, d = solution(data)
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+ Ql, diam, k, Q = q_factor(a)
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+ sigma2A = recalculation_of_data(data, a, c, d, error=True)
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+ sigmaQ0, sigmaQl = random_deviation(a, sigma2A, diam, k, Ql)
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+ if printing:
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+ print(f"Q = {Q} +- {sigmaQ0}, if i == {i}")
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+
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+
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def random_deviation(a, sigma2A, diam, k, Ql):
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"""defines standart deviations of values"""
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- sigmaQl = sigma2A[2]**0.5
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- sigmaDiam = (sigma2A[0]/(abs(a[2])**2) + sigma2A[1] + abs(a[0]/a[2]/a[2])**2 * sigma2A[2])**0.5
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- sigmaK = 2*sigmaDiam/((2-diam)**2)
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- sigmaQ0 = ((1 + k)**2 * sigma2A[2] + Ql**2 * sigmaK**2)**0.5
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+ sigmaQl = sigma2A[2] ** 0.5
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+ sigmaDiam = (sigma2A[0] / (abs(a[2]) ** 2) + sigma2A[1] + abs(a[0] / a[2] / a[2]) ** 2 * sigma2A[2]) ** 0.5
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+ sigmaK = 2 * sigmaDiam / ((2 - diam) ** 2)
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+ sigmaQ0 = ((1 + k) ** 2 * sigma2A[2] + Ql ** 2 * sigmaK ** 2) ** 0.5
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return sigmaQ0, sigmaQl
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@@ -96,13 +110,7 @@ def apply(filename):
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freq, re, im = open_file(filename)
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data = prepare_data(freq, re, im)
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a, c, d = solution(data)
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- for i in range(2, 10):
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- data = recalculation_of_data(data, a, c, d)
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- a, c, d = solution(data)
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- Ql, diam, k, Q = q_factor(a)
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- sigma2A = recalculation_of_data(data, a, c, d, error=True)
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- sigmaQ0, sigmaQl = random_deviation(a, sigma2A, diam, k, Ql)
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- print(f"Q = {Q} +- {sigmaQ0}, if i == {i}")
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+ recalculating(data, a, c, d, 10, printing=True)
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def fl_fitting(freq, re, im):
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@@ -110,42 +118,35 @@ def fl_fitting(freq, re, im):
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data, fl = prepare_data(freq, re, im)
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a, c, d = solution(data)
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-
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+ Ql, Q, sigmaQ0, sigmaQl = None, None, None, None
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# Repeated curve fitting
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# 1.189 of Qfactor Matlab
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# fl2 = 0
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# g_d=0
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# g_c=0
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for x in range(0, 3):
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- g_c = (np.conj(a[2])*a[1]-a[0])/(np.conj(a[2])-a[2])
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- g_d = a[0]/a[2]
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- g_2 = 2*g_c-g_d
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- dt = (a[1]-g_2)/(g_2*a[2]-a[0])
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- fl2 = fl*(1 + np.real(dt)/2)
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+ g_c = (np.conj(a[2]) * a[1] - a[0]) / (np.conj(a[2]) - a[2])
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+ g_d = a[0] / a[2]
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+ g_2 = 2 * g_c - g_d
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+ dt = (a[1] - g_2) / (g_2 * a[2] - a[0])
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+ fl2 = fl * (1 + np.real(dt) / 2)
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data, fl = prepare_data(freq, re, im, fl2)
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a, c, d = solution(data)
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-
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- for i in range(2, 20):
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- data = recalculation_of_data(data, a, c, d)
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- a, c, d = solution(data)
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-
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- Ql, diam, k, Q = q_factor(a)
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- sigma2A = recalculation_of_data(data, a, c, d, error=True)
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- sigmaQ0, sigmaQl = random_deviation(a, sigma2A, diam, k, Ql)
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+ recalculating(data, a, c, d, 20)
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# taking into account coupling losses on page 69 of Qfactor Matlab
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# to get results similar to example program
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- if False:
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- phi1=np.arctan(np.double(g_d.imag/g_d.real)) # 1.239
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- phi2=np.arctan(np.double((g_c.imag-g_d.imag)/(g_c.real-g_d.real)))
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- phi=-phi1+phi2
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- d_s=(1-np.abs(g_d)**2)/(1-np.abs(g_d)*np.cos(phi))
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- diam = abs(a[1] - a[0] / a[2])
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- qk=1/(d_s/diam-1)
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-
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- sigma2A = recalculation_of_data(data, a, c, d, error=True)
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- sigmaQ0 = random_deviation(a, sigma2A, diam, k, Ql)
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- Q = Ql * (1 + qk) # Q-factor = result
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- print(f"Q0 = {Q} +- {sigmaQ0}")
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-
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- return Q,sigmaQ0, Ql, sigmaQl,a
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+ # if False:
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+ # phi1=np.arctan(np.double(g_d.imag/g_d.real)) # 1.239
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+ # phi2=np.arctan(np.double((g_c.imag-g_d.imag)/(g_c.real-g_d.real)))
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+ # phi=-phi1+phi2
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+ # d_s=(1-np.abs(g_d)**2)/(1-np.abs(g_d)*np.cos(phi))
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+ # diam = abs(a[1] - a[0] / a[2])
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+ # qk=1/(d_s/diam-1)
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+ #
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+ # sigma2A = recalculation_of_data(data, a, c, d, error=True)
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+ # sigmaQ0 = random_deviation(a, sigma2A, diam, k, Ql)
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+ # Q = Ql * (1 + qk) # Q-factor = result
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+ # print(f"Q0 = {Q} +- {sigmaQ0}")
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+
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+ return Q, sigmaQ0, Ql, sigmaQl, a
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