#!/usr/bin/env python3 # -*- coding: utf-8 -*- """ Created on Mon Aug 21 16:12:53 2023 @author: astral """ import sys import os import pyqtgraph as qt import pyqtgraph.exporters from PyQt5.QtGui import QFont import math as m import numpy as np def __get_color(factor, gamma=0.8): frequency=380+factor*(750-380) lightfrequency = 0.4*(3*np.log10(frequency/2)-2)/4 wavelength = 300/lightfrequency '''steps of 10Hz: 22 means 220Hz''' '''This converts a given wavelength of light to an approximate RGB color value. The wavelength must be given in values between 0 and 1 for 0=380nm through 1=750nm (789 THz through 400 THz). Based on code by Dan Bruton http://www.physics.sfasu.edu/astro/color/spectra.html ''' wavelength = float(wavelength) if wavelength >= 380 and wavelength <= 440: attenuation = 0.3 + 0.7 * (wavelength - 380) / (440 - 380) R = ((-(wavelength - 440) / (440 - 380)) * attenuation) ** gamma G = 0.0 B = (1.0 * attenuation) ** gamma elif wavelength >= 440 and wavelength <= 490: R = 0.0 G = ((wavelength - 440) / (490 - 440)) ** gamma B = 1.0 elif wavelength >= 490 and wavelength <= 510: R = 0.0 G = 1.0 B = (-(wavelength - 510) / (510 - 490)) ** gamma elif wavelength >= 510 and wavelength <= 580: R = ((wavelength - 510) / (580 - 510)) ** gamma G = 1.0 B = 0.0 elif wavelength >= 580 and wavelength <= 645: R = 1.0 G = (-(wavelength - 645) / (645 - 580)) ** gamma B = 0.0 elif wavelength >= 645 and wavelength <= 750: attenuation = 0.3 + 0.7 * (750 - wavelength) / (750 - 645) R = (1.0 * attenuation) ** gamma G = 0.0 B = 0.0 else: R = 0.0 G = 0.0 B = 0.0 R *= 255 G *= 255 B *= 255 return (int(R), int(G), int(B)) def plot_execute(): if sys.flags.interactive != 1 or not hasattr(qt.QtCore, 'PYQT_VERSION'): qt.QtGui.QApplication.exec_() def qtplot(titletext, spaces, vals, names, x_tag=f'noise level {chr(949)}', y_tag=None, colors=None, export=False, path=None, filename=None, lw=4, close=False): linewidth = lw #app = qt.mkQApp() ph = qt.plot() ph.showGrid(x=True,y=True) ph.setXRange(np.min(spaces), np.max(spaces)) # ph.setYRange(0.0, 6) #ph.setTitle(title='Susceptibility density evolution for different automaton sizes', offset=(1000,500))#.format(dim)) ph.setLabel('left', y_tag) ph.setLabel('bottom', x_tag) #ph.setXRange(0, 0.15) ph.addLegend(offset=(400, 30)) #s = ph.plot(np.linspace(0.01,0.32,32), eps_max_freq0, title=sp_Title, pen='w') #s = ph.plot(np.linspace(0.01,0.32,32), eps_max_freq1, title=sp_Title, pen='w') if colors=='rgb': colors=[__get_color(fac/(len(vals)-1)) for fac in range(len(vals))] elif colors is None: colors=['r', 'g', 'b', 'y', 'c', 'm', 'w', (100,100,0), (0,100,100), (100,0,100)] for i in range(len(vals)): s = ph.plot(spaces[i], vals[i], name=names[i], pen=qt.mkPen(colors[i], width=linewidth)) title_item = qt.TextItem(text=titletext, anchor=(0.5, 7), color='grey') ph.addItem(title_item) title_item.setPos(ph.getViewBox().viewRect().center()) font = QFont() font.setPointSize(14) # Adjust the font size as needed title_item.setFont(font) if export: if not os.path.exists(path): os.makedirs(path) exporter = qt.exporters.ImageExporter(ph.plotItem) # set export parameters if needed exporter.parameters()['width'] = 1200 # (note this also affects height parameter) # save to file exporter.export(path+filename) print(f'Saving to {path+filename}') def handleAppExit(): # Add any cleanup tasks here print("closing") if close: ph.close() # app.aboutToQuit.connect(handleAppExit) # app.exec_()