203 lines
7.0 KiB
Python
203 lines
7.0 KiB
Python
import time
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import numpy as np
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import pylab as plt
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import pandas as pd
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import re
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from scipy.optimize import least_squares
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from model import Model
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from Data import Data
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class Fitter:
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def __init__(self, model: Model, data: Data, current_fit_range: tuple = (107, 341)) -> None:
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"""
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current_fit_range : tuple (t0, t1), t0 nad t1 are start and stop times in between current is fitted
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"""
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self.model = model
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self.data = data
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self.current_fit_range = current_fit_range
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self.fit_results = {}
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self.tspan = [0, 1000]
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self.dt = 1 # 1.0
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self.time_points = np.arange(*self.tspan, self.dt)
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self.iteration = 0 # least squares iteration counter
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t0, t1 = self.current_fit_range = current_fit_range
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self.current_time_indecies = (t0 <= self.time_points) & (self.time_points <= t1)
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self.measured_current = self.data.get_current_slice(
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self.time_points[self.current_time_indecies] / 1000
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) # calculating in ms but data recorded in sec
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def convolve_current(self, current: np.ndarray, tau=1.5):
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if np.abs(tau) < 1e-8:
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return current
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k = np.zeros(current.size)
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k[k.size // 2:] = np.exp(-np.arange(k.size // 2) / np.abs(tau))
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k /= k.sum()
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if tau > 0:
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return np.convolve(current, k, mode="same")
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else:
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return np.convolve(current, k[::-1], mode="same")
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def cost_func(self, parameters: np.ndarray):
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model = self.model()
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gGaL, ECal, K_pc_half, tau_xfer, tau_RC, offset = parameters
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model.ECaL = ECal
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model.gCaL = gGaL
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model.K_pc_half = K_pc_half
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model.tau_xfer = tau_xfer
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model.solve(times=self.time_points)
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_calc_curr = model.calculated_current()
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calculated_current = self.convolve_current(_calc_curr, tau=tau_RC)[self.current_time_indecies] + offset
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res = self.measured_current - calculated_current
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err = np.mean(res**2) # mean squared error
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self.iteration += 1
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print(self.iteration, parameters.tolist(), "err", err)
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# measured_fluo = self.data.fluo
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# fluo_interplolator = interp1d(self.time_domain, model.calculated_fluo)
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# calculated_fluo = fluo_interplolator(self.data.fluo_time)
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if self.iteration < -0:
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t = self.time_points[self.current_time_indecies]
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plt.plot(t, _calc_curr[self.current_time_indecies], label="calculated current")
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plt.plot(t, self.measured_current, label="measured current")
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plt.plot(t, calculated_current, label="conv calculated current")
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plt.plot(t, self.measured_current - calculated_current, label="error")
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plt.xlabel("time, ms")
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plt.ylabel("current, pA/pF")
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plt.legend(frameon=False)
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plt.show()
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# exit()
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return res # , measured_fluo - calculated_fluo)
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def optimize(self, init_parameters=None):
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t0 = time.time()
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self.iteration = 0
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if init_parameters is None:
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m = self.model()
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K_pc_half = m.K_pc_half
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tau_xfer = m.tau_xfer
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tau_RC = 1.5
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offset = 0
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d = self.data
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init_parameters = np.array([d.gGaL, d.ECal, K_pc_half, tau_xfer, tau_RC, offset])
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print(init_parameters.tolist())
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bounds = (
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(0.01, 10, 0.1, 0.1, 0.1, -5, -10),
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(10, 100, 100, 1, 100, 10, 10),
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)
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res = least_squares(self.cost_func, init_parameters, bounds=bounds, xtol=1e-10)
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print()
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print(" Parameters: [gGaL, ECal, K_pc_half, tau_xfer, tau_RC, offset]")
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print(" Initial:", init_parameters.tolist())
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print(" Optimized:", res.x.tolist())
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print(" Optim status:", res.status)
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print("Optim message:", res.message)
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gGaL, ECal, K_pc_half, tau_xfer, tau_RC, offset = res.x
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self.fit_results.update({
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'gGaL': gGaL,
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'ECal': ECal,
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'K_pc_half': K_pc_half,
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'tau_xfer': tau_xfer,
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'tau_RC': tau_RC,
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'offset': offset,
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'mean_squared_error': err})
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model = self.model()
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model.ECaL = ECal
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model.gCaL = gGaL
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model.K_pc_half = K_pc_half
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model.tau_xfer = tau_xfer
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model.solve(times=self.time_points)
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_calc_curr = model.calculated_current()
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calculated_current = self.convolve_current(_calc_curr, tau=tau_RC) + offset
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print("Elapsed time:", time.time() - t0)
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fig = plt.figure(figsize=(24, 12))
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ax1 = fig.add_subplot(121)
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ax2 = fig.add_subplot(122)
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ax1.plot(1000 * self.data.current_t, self.data.current, label="Measured")
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ax1.plot(self.time_points, calculated_current, label="Calculated")
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ax1.set_xlabel("time, ms")
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ax1.set_ylabel("current, pA/pF")
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ax1.legend(frameon=False)
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tp = self.time_points[self.current_time_indecies]
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ax2.plot(tp, self.measured_current, label="Measured")
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ax2.plot(tp, calculated_current[self.current_time_indecies], label="Calculated")
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ax2.set_xlabel("time, ms")
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ax2.set_ylabel("current, pA/pF")
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ax2.legend(frameon=False)
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return res, fig
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def covcor_from_lsq(res):
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_, s, VT = svd(res.jac, full_matrices=False)
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threshold = np.finfo(float).eps * max(res.jac.shape) * s[0]
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s = s[s > threshold]
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VT = VT[: s.size]
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cov = np.dot(VT.T / s**2, VT)
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std = np.sqrt(np.diag(cov))
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cor = cov / np.outer(std, std)
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cor[cov == 0] = 0
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return cov, cor
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def plot_correlation_matrix(cor):
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plt.imshow(cor, cmap='viridis', interpolation='nearest')
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plt.colorbar(label='Correlation')
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plt.title('Correlation Matrix')
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plt.xlabel('Variables')
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plt.ylabel('Variables')
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plt.show()
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if __name__ == "__main__":
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filename = "ltcc_current.h5"
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eid = "0033635a51b096dc449eb9964e70443a67fc16b9587ae3ff6564eea1fa0e3437_2018.06.18 14:48:40"
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data = Data(filename, eid)
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fit = Fitter(Model, data)
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fit_hist = pd.DataFrame.from_dict(fit.fit_results, orient='index').T
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fit_hist.index.name = 'Iterations'
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res_filename = f"fit_results_{eid}.csv"
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res_filename = res_filename.replace(" ", "_").replace(":", "-")
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fit_hist.to_csv(res_filename, index=True)
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eid_cleaned = re.sub(r'[^\w.-]', '', eid) # Eemalda kõik eritähed ja jääb alles alphanumbrilised tähed, sidekriipsud ja punktid
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fig.savefig(f"plot_{eid_cleaned}.png")
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fig.savefig(f"plot_{eid_cleaned}.pdf")
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# plot_filename = "fit_plot"
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# fig.savefig(f"{plot_filename}.png")
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# fig.savefig(f"{plot_filename}.pdf")
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fig.savefig("naidis_fit.pdf")
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plt.show()
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