質問内容
Qtextcursorが引数として使えないとのエラーが表示されます。matplotlob,python,pyqtに精通している方、ご教授お願いします。
以下はコードと, エラーメッセージ
my code
# core GUI libraries
from PyQt5 import QtWidgets, uic, QtCore, QtGui
from PyQt5.QtWidgets import QMainWindow, QFileDialog
#from PyQtCore import QRunnable, QThreadPool, pyqtSlot
# from threading import Thread
import os
import sys
import numpy as np
import pandas as pd
import matplotlib
matplotlib.use('Agg')
import matplotlib.pyplot as plt
from shapely.geometry import LineString
# change matplotlib settings to make plots look nicer
plt.rcParams['xtick.labelsize'] = 20
plt.rcParams['ytick.labelsize'] = 20
plt.rcParams['axes.linewidth'] = 3
plt.rcParams['xtick.minor.width'] = 3
plt.rcParams['xtick.major.width'] = 3
plt.rcParams['ytick.minor.width'] = 3
plt.rcParams['ytick.major.width'] = 3
plt.rcParams['figure.autolayout'] = True
class Worker(QtCore.QRunnable):
"""Class to start a new worker thread for background tasks.
Call this thread inside a main GUI function by:
worker = Worker(self.function_to_execute) # , pass other args here,...,)
self.threadpool.start(worker)
where self.function_to_execute is the function to run and its args
"""
def __init__(self, fn, *args, **kwargs):
"""This allows the Worker class to take any function as an
argument, along with args, and run it in a separate thread."""
super(Worker, self).__init__()
self.fn = fn
self.args = args
self.kwargs = kwargs
@QtCore.pyqtSlot()
def run(self):
"""Take a function and its args which were passed to the Worker
class and execute it in a new thread."""
self.fn(*self.args, **self.kwargs)
class App(QMainWindow):
"""Class which creates the main window of the application."""
# load Qt designer XML .ui GUI file
Ui_MainWindow, QtBaseClass = uic.loadUiType('ui.ui')
def __init__(self):
super(App, self).__init__()
self.ui = App.Ui_MainWindow()
self.ui.setupUi(self)
# initialize multithreading
self.threadpool = QtCore.QThreadPool()
# assign functions to top menu items
# example: self.ui.menu_item_name.triggered.connect(self.function_name)
self.ui.actionShowfiledir.triggered.connect(self.show_directory)
self.ui.actionChangefiledir.triggered.connect(self.set_directory)
self.ui.actionQuit.triggered.connect(self.quitapp)
# assign actions to GUI buttons
# example: self.ui.BUTTON_NAME.clicked.connect(self.FUNCTION_NAME)
self.ui.fit_model.clicked.connect(self.fit_model_in_new_thread)
self.ui.plot_df_surf.clicked.connect(self.plot_df_surf)
self.ui.plot_dd_surf.clicked.connect(self.plot_dd_surf)
self.ui.plot_sol_surf.clicked.connect(self.plot_sol_surf)
self.ui.export_results.clicked.connect(self.export_results)
# assign actions to checkboxes
# example: self.ui.CHECKBOX.stateChanged.connect(self.FUNCTION_NAME)
# set default data folder and create it if it doesn't exist
self.filedir = os.getcwd()+'\\QCMD_model_results'
if not os.path.exists(self.filedir):
os.makedirs(self.filedir)
# %% ----------- system control functions ------------------------------
# file I/O utilities ---------------------------------------------------
def export_results(self):
"""Save modeling results to file."""
filename = 'QCMD_results'
filepath = self.filedir + '\\' + filename + '.csv'
df = pd.DataFrame(list(self.results.items()))
df.to_csv(filepath)
self.ui.outbox.append('\nFile saved to ' + filepath)
def set_directory(self):
"""Set the directory for saving files."""
self.filedir = str(QFileDialog.getExistingDirectory(
self, 'Select a directory for storing data'))
self.ui.outbox.append('\nFile directory is set to ' + self.filedir)
def show_directory(self):
"""Show the file directory in the output box."""
self.ui.outbox.append('\nFile directory is set to ' + self.filedir)
def fit_model_in_new_thread(self):
"""Run Kelvin-Voigt model in new thread."""
worker = Worker(self.fit_model) # pass other args here
self.threadpool.start(worker)
def get_ui_inputs(self):
"""Get a dictionary of inputs from the UI."""
uidict = {
'f0': float(self.ui.f0.currentText())*1e6,
'n': int(self.ui.n.currentText()),
'rho': float(self.ui.film_density.value()),
'h': float(self.ui.film_thickness.value())*1e-9,
'medium': str(self.ui.medium.currentText()),
'df_exp': float(self.ui.df_exp.value()),
'dd_exp': float(self.ui.dd_exp.value()),
'mu_low': int(self.ui.mu_exp_low.value()),
'mu_high': int(self.ui.mu_exp_high.value()),
'eta_low': int(self.ui.eta_exp_low.value()),
'eta_high': int(self.ui.eta_exp_high.value())}
return uidict
def mu_eta_mesh(self, uidict):
"""Create mesh of mu and eta valuses using inputs on UI."""
# get 2D 1mesh grid points of log mu and eta values
step_num=50
mu_mesh, eta_mesh = np.meshgrid(
np.linspace(uidict['mu_low'], uidict['mu_high'],
step_num).astype(float),
np.linspace(uidict['eta_low'], uidict['eta_high'],
step_num).astype(float))
#get mesh of mu and eta values and corresponding DF and DD values
df_surf, dd_surf = self.kelvin_voigt(
10**mu_mesh,
10**eta_mesh,
rho_f=uidict['rho'],
h_f=uidict['h'],
n=uidict['n'],
f0=uidict['f0'],
medium=uidict['medium'])
return mu_mesh, eta_mesh, df_surf, dd_surf
def fit_model(self):
"""Run modeling of the QCM-D dtaa using inputs from UI. """
self.ui.fit_model.setDisabled(True)
self.ui.outbox.append('------------------------------------------')
self.ui.outbox.append('Fitting model...')
# get dictionary of input values from UI
uidict = self.get_ui_inputs()
self.results = uidict.copy()
self.contours = {}
# get grid of possible mu, eta, df, and dd values
mu_mesh, eta_mesh, df_surf, dd_surf = self.mu_eta_mesh(uidict)
# plot delta F heatmap
plt.ioff()
df_cont_plot = plt.contour(
mu_mesh, eta_mesh, df_surf, uidict['df_exp'])
# plot delta D heatmap
dd_cont_plot = plt.contour(
mu_mesh, eta_mesh, dd_surf, uidict['dd_exp'])
# extract contours which correspond to experimental values
df_cont = self.get_contour(df_cont_plot)
dd_cont = self.get_contour(dd_cont_plot)
# find intersection of solutions
intersection_list = np.array(
self.find_intersections(df_cont, dd_cont))
plt.cla()
# if there are any solutions, select the 0th-order solution
if len(intersection_list) > 0:
sol = sorted(intersection_list, key = lambda i: float(i[1]))[-1]
# get calculated mu and eta values, along with G' and G''
mu, eta, = 10**sol[0], 10**sol[1]
Gp, Gdp = mu, 2*np.pi*uidict['f0']*eta
# get fitted df and dd values
df_fit, dd_fit = self.kelvin_voigt(mu, eta,
rho_f=uidict['rho'],
h_f=uidict['h'],
n=uidict['n'],
f0=uidict['f0'],
medium=uidict['medium'])
# get penetration depth
pen_dep = self.get_penetration_depth(uidict['f0'], eta,
uidict['rho'])
self.results.update({'df_fit': df_fit, 'dd_fit': dd_fit,
'mu': mu, 'eta': eta,
'penetration_depth': pen_dep,
"G'": Gp, "G''": Gdp})
self.contours.update({'df_exp': uidict['df_exp'],
'dd_exp': uidict['dd_exp'],
'mu_mesh': mu_mesh, 'eta_mesh': eta_mesh,
'df_surf': df_surf, 'dd_surf': dd_surf,
'df_cont': df_cont, 'dd_cont': dd_cont,
'sol': sol})
self.ui.outbox.append(
'Found '+str(len(intersection_list))+' solutions.')
self.ui.outbox.append('First-order solution:')
self.ui.plot_sol_surf.setDisabled(False)
self.ui.plot_df_surf.setDisabled(False)
self.ui.plot_dd_surf.setDisabled(False)
self.ui.export_results.setDisabled(False)
for key in self.results:
self.ui.outbox.append(str(key)+': '+str(self.results[key]))
else:
self.ui.outbox.append(
'\n\nNo solutions exist with these parameters.')
self.ui.plot_sol_surf.setDisabled(True)
self.ui.plot_df_surf.setDisabled(True)
self.ui.plot_dd_surf.setDisabled(True)
self.ui.export_results.setDisabled(True)
self.ui.fit_model.setDisabled(False)
self.ui.outbox.moveCursor(QtGui.QTextCursor.End)
def plot_df_surf(self):
"""Plot delta F surface."""
plt.cla()
fig_df = plt.figure(5)
plt.ion()
plt.contour(self.contours['mu_mesh'], self.contours['eta_mesh'],
self.contours['df_surf'], self.contours['df_exp'])
plt.contourf(self.contours['mu_mesh'], self.contours['eta_mesh'],
self.contours['df_surf'], 50, cmap='rainbow')
self.plot_setup(title='Δf (Hz/cm^2)',
labels=['Log (μ) (Pa)', 'Log (η) (Pa s)'], colorbar=True)
plt.tight_layout()
fig_df.canvas.set_window_title('Δf surface')
fig_df.show()
def plot_dd_surf(self):
"""Plot delta D surface."""
plt.cla()
fig_dd = plt.figure(2)
plt.ion()
plt.contour(self.contours['mu_mesh'], self.contours['eta_mesh'],
self.contours['dd_surf'], self.contours['dd_exp'])
plt.contourf(self.contours['mu_mesh'], self.contours['eta_mesh'],
self.contours['dd_surf'], 50, cmap='rainbow')
self.plot_setup(title='ΔD (x 10^-6)',
labels=['Log (μ) (Pa)', 'Log (η) (Pa s)'], colorbar=True)
plt.tight_layout()
fig_dd.canvas.set_window_title('ΔD surface')
fig_dd.show()
def plot_sol_surf(self):
"""Plot solution surface."""
plt.cla()
fig_df = plt.figure(3)
plt.ion()
plt.scatter(self.contours['sol'][0],
self.contours['sol'][1], marker='x',
s=300, c='k', label='solution')
# plot contour intersection
plt.scatter(self.contours['df_cont'][:, 0],
self.contours['df_cont'][:, 1], s=1, c='b', label='df')
plt.scatter(self.contours['dd_cont'][:, 0],
self.contours['dd_cont'][:, 1], s=1, c='r', label='dd')
self.plot_setup(title='Solution',
labels=['Log (μ) (Pa)', 'Log (η) (Pa s)'], legend=True)
plt.tight_layout()
fig_df.canvas.set_window_title('Solution')
fig_df.show()
def plot_setup(self, labels=['X', 'Y'], fsize=20, setlimits=False,
title=None, legend=False, colorbar=False,
limits=[0,1,0,1], save=False, filename='plot.jpg'):
"""Creates a custom plot configuration to make graphs look nice.
This can be called with matplotlib for setting axes labels,
titles, axes ranges, and the font size of plot labels.
This should be called between plt.plot() and plt.show() commands."""
plt.xlabel(str(labels[0]), fontsize=fsize)
plt.ylabel(str(labels[1]), fontsize=fsize)
fig = plt.gcf()
fig.set_size_inches(6, 4)
if title:
plt.title(title, fontsize=fsize)
if legend:
plt.legend(fontsize=fsize-4)
if setlimits:
plt.xlim((limits[0], limits[1]))
plt.ylim((limits[2], limits[3]))
if colorbar:
plt.colorbar()
if save:
fig.savefig(filename, dpi=120, bbox_inches='tight')
plt.tight_layout()
def kelvin_voigt(self, mu_f, eta_f, rho_f=1e3, h_f=1e-6, n=1, f0=5e6,
medium='air'):
"""
The Kelvin-Voigt model comes from eqns (15) in the paper by
Voinova: Vionova, M.V., Rodahl, M., Jonson, M. and Kasemo, B., 1999.
Viscoelastic acoustic response of layered polymer films at fluid-solid
interfaces: continuum mechanics approach. Physica Scripta, 59(5), p.391.
Reference: https://github.com/88tpm/QCMD/blob/master
/Mass-specific%20activity/Internal%20functions/voigt_rel.m.
This function solves for Delta f and Delta d of thin adlayer on QCM.
It differs from voigt because it calculates relative to an
unloaded resonator.
Inputs
mu_f = shear modulus of film in Pa
eta_f = shear viscosity of film in Pa s
rho_f = density of film in kg m-3
h_f = thickness of film in m
n = crystal harmonic number
f0 = fundamental resonant frequency of crystal in Hz
Output
deltaf = frequency change of resonator
deltad = dissipation change of resonator
"""
# define properties of QCM crystal
w = 2*np.pi*f0*n # angular frequency
mu_q = 2.947e10 # shear modulus of AT-cut quatz in Pa
rho_q = 2648 # density of quartz (kg/m^3)
h_q = np.sqrt(mu_q/rho_q)/(2*f0) # thickness of quartz
# define properties of medium
if medium == 'air':
rho_b = 1.1839 # density of bulk air (25 C) in kg/m^3
eta_b = 18.6e-6 # viscosity of bulk air (25 C) in Pa s
if medium == 'water':
rho_b = 1000 # density of bulk water in kg/m^3
eta_b = 8.9e-4 # viscosity of bulk water in Pa s
# define equations from the Kelvin-Voigt model in publication
# eqn 14
kappa_f = eta_f-(1j*mu_f/w)
# eqn 13
x_f = np.sqrt(-rho_f*np.square(w)/(mu_f + 1j*w*eta_f))
x_b = np.sqrt(1j*rho_b*w/eta_b)
# eqn 11 after simplification with h1 = h2 and h3 = infinity
A = (kappa_f*x_f+eta_b*x_b)/(kappa_f*x_f-eta_b*x_b)
# eqn 16
beta = kappa_f*x_f*(1-A*np.exp(2*x_f*h_f))/(1+A*np.exp(2*x_f*h_f))
beta0 = kappa_f*x_f*(1-A)/(1+A)
# eqn 15
df = np.imag((beta-beta0)/(2*np.pi*rho_q*h_q))
dd = -np.real((beta-beta0)/(np.pi*f0*n*rho_q*h_q))*1e6
return df, dd
def get_contour(self, cont_plot):
"""Get ordered pairs of contour lines from a contour plot.
Input should be defined as:
cont_plot = plt.contour(x_mesh, y_mesh, z_surf, contour_value)"""
# extract contour paths from plot
paths = [path.vertices for path in cont_plot.collections[0].get_paths()]
if paths:
# stack all contour paths in a single 2D array
return np.vstack(paths)
else:
return []
def find_intersections(self, op_list1, op_list2):
"""Find all intersections between two curves. Curves are defined by lists
of ordered pairs (x, y).
Returns an empty list if no intersections are found."""
intersections = []
# check if both curves contain more than 1 point:
if len(op_list1) > 1 and len(op_list2) > 1:
# loop over each pair of line segments
for i1 in range(len(op_list1)-1):
for i2 in range(len(op_list2)-1):
# create segment from the first set of points
seg1 = LineString([(op_list1[i1][0], op_list1[i1][1]),
(op_list1[i1+1][0], op_list1[i1+1][1])])
# create segment from the second set of points
seg2 = LineString([(op_list2[i2][0], op_list2[i2][1]),
(op_list2[i2+1][0], op_list2[i2+1][1])])
# check if segment from set-1 intersects segment from set-2
if seg1.intersects(seg2):
avg_x = np.mean([op_list1[i1][0], op_list1[i1+1][0],
op_list2[i2][0], op_list2[i2+1][0]])
avg_y = np.mean([op_list1[i1][1], op_list1[i1+1][1],
op_list2[i2][1], op_list2[i2+1][1]])
intersections.append([avg_x, avg_y])
return intersections
def get_penetration_depth(self, freq, eta, rho):
"""Calculate penetration depth of acoustic wave using the QCM
resonant requency (freq), adlayer visacosity (eta), and adlayer
density (rho)."""
return np.sqrt(eta / (np.pi * freq * rho))
def quitapp(self):
"""Quit the application."""
self.deleteLater()
# self.timer.stop() # stop timer
# close app window
self.close()
# kill python kernel
sys.exit()
# %% -------------------------- run application ----------------------------
if __name__ == "__main__":
if not QtWidgets.QApplication.instance():
app = QtWidgets.QApplication(sys.argv)
else:
app = QtWidgets.QApplication.instance()
window = App()
window.show()
sys.exit(app.exec_())
error message
C:\Users\vlrgx\OneDrive\デスクトップ\python_lesson>python app.py
QObject::connect: Cannot queue arguments of type 'QTextCursor'
(Make sure 'QTextCursor' is registered using qRegisterMetaType().)
Traceback (most recent call last):
File "C:\Users\vlrgx\OneDrive\デスクトップ\python_lesson\app.py", line 92, in run
self.fn(*self.args, **self.kwargs)
File "C:\Users\vlrgx\OneDrive\デスクトップ\python_lesson\app.py", line 228, in fit_model
df_cont_plot = plt.contour(
^^^^^^^^^^^^
File "C:\Users\vlrgx\AppData\Local\Programs\Python\Python312\Lib\site-packages\matplotlib\pyplot.py", line 2939, in contour
__ret = gca().contour(
^^^^^^^^^^^^^^
File "C:\Users\vlrgx\AppData\Local\Programs\Python\Python312\Lib\site-packages\matplotlib\__init__.py", line 1478, in inner
return func(ax, *map(sanitize_sequence, args), **kwargs)
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
File "C:\Users\vlrgx\AppData\Local\Programs\Python\Python312\Lib\site-packages\matplotlib\axes\_axes.py", line 6520, in contour
contours = mcontour.QuadContourSet(self, *args, **kwargs)
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
File "C:\Users\vlrgx\AppData\Local\Programs\Python\Python312\Lib\site-packages\matplotlib\contour.py", line 858, in __init__
kwargs = self._process_args(*args, **kwargs)
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
File "C:\Users\vlrgx\AppData\Local\Programs\Python\Python312\Lib\site-packages\matplotlib\contour.py", line 1523, in _process_args
x, y, z = self._contour_args(args, kwargs)
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
File "C:\Users\vlrgx\AppData\Local\Programs\Python\Python312\Lib\site-packages\matplotlib\contour.py", line 1574, in _contour_args
self._process_contour_level_args(args, z.dtype)
File "C:\Users\vlrgx\AppData\Local\Programs\Python\Python312\Lib\site-packages\matplotlib\contour.py", line 1237, in _process_contour_level_args
if len(self.levels) > 1 and np.min(np.diff(self.levels)) <= 0.0:
^^^^^^^^^^^^^^^^
TypeError: len() of unsized object
