示例#1
0
    def cargarSenial(self):
        self.aux = False
        self.list3.clear()
        self.list_MDFA.clear()
        self.plot1.clear()
        self.nombreSenial = QFileDialog.getOpenFileNames(
            None, 'Open file(s)', '/home')
        self.rutas = self.nombreSenial[0]

        self.dialog = Dialog(
            str(len(self.rutas)) + ' Files(s) loaded', 'open.png')
        self.dialog.show()
        self.list3.addItem('')
        for i in range(len(self.rutas)):
            names = str.split(self.rutas[i], "/")
            t = len(names)
            nombre = names[t - 1]
            self.list3.addItem(nombre)

        if (len(self.rutas) == 0):
            self.lbl_num_files.setStyleSheet("color : red; ")
            self.lbl_num_files.setText("Files loaded: " + str(len(self.rutas)))
        else:
            self.lbl_num_files.setStyleSheet("color : blue; ")
            self.lbl_num_files.setText("Files loaded: " + str(len(self.rutas)))
        self.aux = True
        self.btnMDFA.setEnabled(True)
示例#2
0
文件: main.py 项目: Ulipaeh/mdfaPy
 def addInterval(self):
     duracion = []
     contador = 0
     if (len(self.txtns.text()) == 0):
         self.dialogo_error = Dialog(
             'A segment number must be type() = int ', 'Icons\error.png')
         self.dialogo_error.show()
     else:
         contador = int(self.txtns.text())
         regionSelected = self.lr.getRegion()
         ini = int(regionSelected[0])
         fin = int(regionSelected[1])
         duracion.append(self.y[ini:fin])
         duracion = transpose(duracion)
         df = DataFrame(duracion)
         names = str.split(self.nombreSenial[0], self.nombre)
         nam = str.split(self.nombre, '.')
         df.to_csv(names[0] + nam[0] + '_seg_' + str(contador) + '.txt',
                   index=False,
                   sep='\t',
                   header=None,
                   mode='w')
         duracion = []
         linea1 = pg.InfiniteLine(pos=ini, angle=90, movable=False)
         linea2 = pg.InfiniteLine(pos=fin, angle=90, movable=False)
         self.plot1.addItem(linea1)
         self.plot1.addItem(linea2)
         self.lr.setRegion([fin, fin + 6000])
示例#3
0
文件: main.py 项目: Ulipaeh/mdfaPy
    def autoseg(self):
        self.aux == False
        self.inicio = []
        self.final = []
        self.seg_pos.clear()
        self.seg_pos.addItem('')

        def group_consecutives(vals, step=1):
            run = []
            result = [run]
            expect = None
            for v in vals:
                if (v == expect) or (expect is None):
                    run.append(v)
                else:
                    run = [v]
                    result.append(run)
                expect = v + step
            return result

        if (len(self.txt_umbral.text()) != 0
                and len(self.txt_basal.text()) != 0
                and len(self.txt_ancho.text()) != 0
                and len(self.txt_separacion.text()) != 0):
            umbral = float(self.txt_umbral.text())
            basal = float(self.txt_basal.text())
            ancho = float(self.txt_ancho.text())
            separacion = float(self.txt_separacion.text())
            y = self.y_auto

            loc_x = []
            for i in range(len(y)):
                if (y[i] > umbral):
                    loc_x.append(i)

            pico_range = group_consecutives(loc_x)

            loc_x1 = []
            for i in range(len(pico_range)):
                aux = pico_range[i]
                pico = list(y[aux])
                pos_aux = pico.index(max(pico))
                loc_x1.append(aux[pos_aux])

            loc = []
            loc.append(loc_x[0])
            for i in range(1, len(loc_x1)):
                if (loc_x1[i] - loc_x1[i - 1] > ancho):
                    loc.append(loc_x1[i])

            ini = []
            end = []
            for i in range(len(loc)):
                if (loc[0] > 2 * separacion):
                    x_ini = arange(loc[i] - separacion, loc[i])
                    y_ini = y[x_ini]

                    x_end = arange(loc[i], loc[i] + separacion)
                    y_end = y[x_end]

                    donde_ini = where(y_ini <= min(y_ini) + basal)[0]
                    donde_fin = where(y_end <= min(y_ini) + basal)[0]

                    if (len(donde_fin) != 0 and len(donde_ini) != 0):
                        ini.append(x_ini[max(donde_ini)])
                        end.append(x_end[min(donde_fin)])
                elif (loc[0] < separacion):
                    x_ini = arange(0, loc[i])
                    y_ini = y[x_ini]

                    x_end = arange(loc[i], loc[i] + separacion)
                    y_end = y[x_end]

                    donde_ini = where(y_ini <= min(y_ini) + basal)[0]
                    donde_fin = where(y_end <= min(y_ini) + basal)[0]

                    if (len(donde_fin) != 0 and len(donde_ini) != 0):
                        ini.append(x_ini[max(donde_ini)])
                        end.append(x_end[min(donde_fin)])

                elif (len(y) - (loc[len(loc) - 1] + separacion) < 0):
                    x_ini = arange(loc[i] - separacion, loc[i])
                    y_ini = y[x_ini]

                    x_end = arange(loc[i], len(y))
                    y_end = y[x_end]

                    donde_ini = where(y_ini <= min(y_ini) + basal)[0]
                    donde_fin = where(y_end <= min(y_ini) + basal)[0]

                    if (len(donde_fin) != 0):
                        ini.append(x_ini[max(donde_ini)])
                        end.append(x_end[min(donde_fin)])
            ini = list(set(ini))
            end = list(set(end))
            ini = list(sorted(ini))
            end = list(sorted(end))
            names = str.split(self.nombreSenial[0], self.nombre)
            nam = str.split(self.nombre, '.')

            for i in range(len(ini)):
                self.seg_pos.addItem(str(i + 1))
                self.inicio.append(int(ini[i]))
                self.final.append(int(end[i]))
                data = DataFrame(y[int(ini[i]):int(end[i])])
                data.to_csv(names[0] + nam[0] + '_seg_' + str(i + 1) + '.txt',
                            sep='\t',
                            header=None,
                            index=False)
            self.aux = True
            self.txt_total.setText(str(len(self.inicio)))
            self.btn_loc.setEnabled(True)
            self.btnauto.setEnabled(False)
        elif (len(self.txt_umbral.text()) != 0
              or len(self.txt_basal.text()) != 0
              or len(self.txt_ancho.text()) != 0
              or len(self.txt_separacion.text()) != 0):
            self.dialogo_error = Dialog('Error: Missing value ',
                                        'Icons\error.png')
            self.dialogo_error.show()
        elif (len(self.txt_umbral.text()) != 0
              and len(self.txt_basal.text()) != 0
              and len(self.txt_ancho.text()) != 0
              and len(self.txt_separacion.text()) != 0):
            self.dialogo_error = Dialog('Error: Missing value ',
                                        'Icons\error.png')
            self.dialogo_error.show()
示例#4
0
文件: main.py 项目: Ulipaeh/mdfaPy
class Principal(QMainWindow):
    def __init__(self):
        super().__init__()
        self.initUI()

    def DFA_boton(self):
        self.DFAWindow = DFA()
        self.DFAWindow.show()

    def MFDFA_boton(self):
        self.MFDFAWindow = MDFA()
        self.MFDFAWindow.show()
#%%

    def cargarSenial(self):
        self.txt_total.setText('')
        self.lbl_inicio.setText('')
        self.lbl_final.setText('')
        self.seg_pos.clear()
        self.btnIniciar.setEnabled(True)
        self.plot1.clear()
        self.nombreSenial = QFileDialog.getOpenFileName(
            None, 'Open file', '/home')
        if (len(self.nombreSenial[0]) != 0):
            print(self.nombreSenial)
            datos = read_csv(self.nombreSenial[0], sep='\t', header=None)
            lineas = datos.shape[1]
            if (lineas == 1):
                self.y = asarray(datos[0])
                self.y_auto = datos[0]
            elif (lineas == 2):
                self.y = asarray(datos[1])
                self.y_auto = datos[1]
            self.plot1.setLabel('bottom', color='k', **{'font-size': '14pt'})
            self.plot1.getAxis('bottom').setPen(pg.mkPen(color='k', width=1))
            # Y1 axis
            self.plot1.setLabel('left', color='k', **{'font-size': '14pt'})
            self.plot1.getAxis('left').setPen(pg.mkPen(color='k', width=1))
            names = str.split(self.nombreSenial[0], "/")
            t = len(names)
            self.nombre = names[t - 1]
            self.plot1.setTitle(self.nombre)
            self.plot1.plot(self.y, pen='k')
            self.btnauto.setEnabled(True)
#%%

    def localizacion(self):
        if (self.aux == True):
            i = self.seg_pos.currentIndex()
            if (i == 0):
                self.lbl_inicio.setText('ini')
                self.lbl_final.setText('end')
            else:
                self.lbl_inicio.setText(str(self.inicio[i - 1]))
                self.lbl_final.setText(str(self.final[i - 1]))
#%%

    def colocar(self):
        inicio = int(self.lbl_inicio.text())
        final = int(self.lbl_final.text())
        if (self.aux2 == True):
            self.lr.setRegion([inicio, final])

#%%

    def autoseg(self):
        self.aux == False
        self.inicio = []
        self.final = []
        self.seg_pos.clear()
        self.seg_pos.addItem('')

        def group_consecutives(vals, step=1):
            run = []
            result = [run]
            expect = None
            for v in vals:
                if (v == expect) or (expect is None):
                    run.append(v)
                else:
                    run = [v]
                    result.append(run)
                expect = v + step
            return result

        if (len(self.txt_umbral.text()) != 0
                and len(self.txt_basal.text()) != 0
                and len(self.txt_ancho.text()) != 0
                and len(self.txt_separacion.text()) != 0):
            umbral = float(self.txt_umbral.text())
            basal = float(self.txt_basal.text())
            ancho = float(self.txt_ancho.text())
            separacion = float(self.txt_separacion.text())
            y = self.y_auto

            loc_x = []
            for i in range(len(y)):
                if (y[i] > umbral):
                    loc_x.append(i)

            pico_range = group_consecutives(loc_x)

            loc_x1 = []
            for i in range(len(pico_range)):
                aux = pico_range[i]
                pico = list(y[aux])
                pos_aux = pico.index(max(pico))
                loc_x1.append(aux[pos_aux])

            loc = []
            loc.append(loc_x[0])
            for i in range(1, len(loc_x1)):
                if (loc_x1[i] - loc_x1[i - 1] > ancho):
                    loc.append(loc_x1[i])

            ini = []
            end = []
            for i in range(len(loc)):
                if (loc[0] > 2 * separacion):
                    x_ini = arange(loc[i] - separacion, loc[i])
                    y_ini = y[x_ini]

                    x_end = arange(loc[i], loc[i] + separacion)
                    y_end = y[x_end]

                    donde_ini = where(y_ini <= min(y_ini) + basal)[0]
                    donde_fin = where(y_end <= min(y_ini) + basal)[0]

                    if (len(donde_fin) != 0 and len(donde_ini) != 0):
                        ini.append(x_ini[max(donde_ini)])
                        end.append(x_end[min(donde_fin)])
                elif (loc[0] < separacion):
                    x_ini = arange(0, loc[i])
                    y_ini = y[x_ini]

                    x_end = arange(loc[i], loc[i] + separacion)
                    y_end = y[x_end]

                    donde_ini = where(y_ini <= min(y_ini) + basal)[0]
                    donde_fin = where(y_end <= min(y_ini) + basal)[0]

                    if (len(donde_fin) != 0 and len(donde_ini) != 0):
                        ini.append(x_ini[max(donde_ini)])
                        end.append(x_end[min(donde_fin)])

                elif (len(y) - (loc[len(loc) - 1] + separacion) < 0):
                    x_ini = arange(loc[i] - separacion, loc[i])
                    y_ini = y[x_ini]

                    x_end = arange(loc[i], len(y))
                    y_end = y[x_end]

                    donde_ini = where(y_ini <= min(y_ini) + basal)[0]
                    donde_fin = where(y_end <= min(y_ini) + basal)[0]

                    if (len(donde_fin) != 0):
                        ini.append(x_ini[max(donde_ini)])
                        end.append(x_end[min(donde_fin)])
            ini = list(set(ini))
            end = list(set(end))
            ini = list(sorted(ini))
            end = list(sorted(end))
            names = str.split(self.nombreSenial[0], self.nombre)
            nam = str.split(self.nombre, '.')

            for i in range(len(ini)):
                self.seg_pos.addItem(str(i + 1))
                self.inicio.append(int(ini[i]))
                self.final.append(int(end[i]))
                data = DataFrame(y[int(ini[i]):int(end[i])])
                data.to_csv(names[0] + nam[0] + '_seg_' + str(i + 1) + '.txt',
                            sep='\t',
                            header=None,
                            index=False)
            self.aux = True
            self.txt_total.setText(str(len(self.inicio)))
            self.btn_loc.setEnabled(True)
            self.btnauto.setEnabled(False)
        elif (len(self.txt_umbral.text()) != 0
              or len(self.txt_basal.text()) != 0
              or len(self.txt_ancho.text()) != 0
              or len(self.txt_separacion.text()) != 0):
            self.dialogo_error = Dialog('Error: Missing value ',
                                        'Icons\error.png')
            self.dialogo_error.show()
        elif (len(self.txt_umbral.text()) != 0
              and len(self.txt_basal.text()) != 0
              and len(self.txt_ancho.text()) != 0
              and len(self.txt_separacion.text()) != 0):
            self.dialogo_error = Dialog('Error: Missing value ',
                                        'Icons\error.png')
            self.dialogo_error.show()

#%%

    def enabledButtons(self):
        self.btnAdd.setEnabled(True)
        self.txtns.setEnabled(True)
        self.plot1.addItem(self.lr)
        self.btnIniciar.setEnabled(False)
        self.aux2 = True
#%%

    def addInterval(self):
        duracion = []
        contador = 0
        if (len(self.txtns.text()) == 0):
            self.dialogo_error = Dialog(
                'A segment number must be type() = int ', 'Icons\error.png')
            self.dialogo_error.show()
        else:
            contador = int(self.txtns.text())
            regionSelected = self.lr.getRegion()
            ini = int(regionSelected[0])
            fin = int(regionSelected[1])
            duracion.append(self.y[ini:fin])
            duracion = transpose(duracion)
            df = DataFrame(duracion)
            names = str.split(self.nombreSenial[0], self.nombre)
            nam = str.split(self.nombre, '.')
            df.to_csv(names[0] + nam[0] + '_seg_' + str(contador) + '.txt',
                      index=False,
                      sep='\t',
                      header=None,
                      mode='w')
            duracion = []
            linea1 = pg.InfiniteLine(pos=ini, angle=90, movable=False)
            linea2 = pg.InfiniteLine(pos=fin, angle=90, movable=False)
            self.plot1.addItem(linea1)
            self.plot1.addItem(linea2)
            self.lr.setRegion([fin, fin + 6000])

#%%

    def reboot(self):
        self.contador = 0
        self.valorContador.setText("")


#%%

    def initUI(self):
        pg.setConfigOption('background', 'w')
        self.setWindowTitle('PyMFDFA')
        self.setWindowIcon(QIcon("Icons\multifractal.ico"))
        ##################################################################
        ### Barra de Herramientas
        ##################################################################
        self.barra_estado = QStatusBar()
        self.setStatusBar(self.barra_estado)

        barra_herr = QToolBar("Toolbar")
        self.addToolBar(barra_herr)

        barra_menu = QMenuBar()
        self.setMenuBar(barra_menu)

        abrir_action = QAction(QIcon('Icons/open.png'), 'Load Signal', self)
        abrir_action.setToolTip('Load Signal')
        abrir_action.setStatusTip('Load signal to segment')
        abrir_action.triggered.connect(self.cargarSenial)
        barra_herr.addAction(abrir_action)
        barra_herr.addSeparator()

        DFA_action = QAction(QIcon('Icons/DFA.ico'),
                             'Detrended Analysis Fluctuation', self)
        DFA_action.setToolTip('Detrended Analysis Fluctuation')
        DFA_action.setStatusTip('Detrended Analysis Fluctuation')
        DFA_action.triggered.connect(self.DFA_boton)
        barra_herr.addAction(DFA_action)

        MDFA_action = QAction(QIcon('Icons/multifractal.ico'),
                              'Multifractal Detrended Analysis Fluctuation',
                              self)
        MDFA_action.setToolTip('Multifractal Detrended Analysis Fluctuation')
        MDFA_action.setStatusTip('Multifractal Detrended Analysis Fluctuation')
        MDFA_action.triggered.connect(self.MFDFA_boton)
        barra_herr.addAction(MDFA_action)
        #################################################################
        ##     Definición de variables globales
        #################################################################
        self.nombreSenial = ''
        self.y = []
        self.aux = 0
        self.aux2 = False
        #################################################################
        ##     Definición de elementos contenedores
        #################################################################
        contain = QSplitter(Qt.Horizontal)
        graficos = QVBoxLayout()
        botones = QVBoxLayout()
        results2 = QFormLayout()
        results3 = QFormLayout()
        results = QFormLayout()
        #################################################################
        ##     Elementos del layout botones
        #################################################################
        #Region for segment in signal
        self.lr = pg.LinearRegionItem([0, 6000])

        btnLoadSig = QPushButton('Load signal')
        btnLoadSig.clicked.connect(self.cargarSenial)
        btnLoadSig.setStyleSheet("font-size: 18px")

        self.btnIniciar = QPushButton('Start segmentation')
        self.btnIniciar.clicked.connect(self.enabledButtons)
        self.btnIniciar.setEnabled(False)
        self.btnIniciar.setStyleSheet("font-size: 18px")

        self.btnAdd = QPushButton('Add segment')
        self.btnAdd.clicked.connect(self.addInterval)
        self.btnAdd.setEnabled(False)
        self.btnAdd.setStyleSheet("font-size: 18px")

        txtnumseg = QLabel("Segment num:")
        txtnumseg.setStyleSheet("font-size: 18px")

        validator = QIntValidator()
        validator.setRange(100, 999)

        self.txtns = QLineEdit()
        self.txtns.setValidator(validator)
        self.txtns.setEnabled(False)

        lbl_umbral = QLabel('Upper threshold:')
        lbl_umbral.setStyleSheet("font-size: 18px")
        self.txt_umbral = QLineEdit()

        lbl_basal = QLabel('Lower threshold')
        lbl_basal.setStyleSheet("font-size: 18px")
        self.txt_basal = QLineEdit()

        lbl_ancho = QLabel('Segment width ')
        lbl_ancho.setStyleSheet("font-size: 18px")
        self.txt_ancho = QLineEdit()

        lbl_separacion = QLabel('Distance:')
        lbl_separacion.setStyleSheet("font-size: 18px")
        self.txt_separacion = QLineEdit()

        self.btnauto = QPushButton('Start auto-segmentation')
        self.btnauto.clicked.connect(self.autoseg)
        self.btnauto.setStyleSheet("font-size: 18px")
        self.btnauto.setEnabled(False)

        lbl_total = QLabel('# of segments:')
        lbl_total.setStyleSheet('font-size: 18px')

        self.txt_total = QLabel()
        self.txt_total.setStyleSheet('font-size: 18px')

        lbl_file = QLabel('Segment: ')
        lbl_file.setStyleSheet("font-size: 18px")
        self.seg_pos = QComboBox()
        self.seg_pos.currentIndexChanged.connect(self.localizacion)

        self.lbl_inicio = QLabel()
        self.lbl_inicio.setStyleSheet("font-size: 18px")
        self.lbl_final = QLabel()
        self.lbl_final.setStyleSheet("font-size: 18px")

        self.btn_loc = QPushButton('Find segment')
        self.btn_loc.setStyleSheet("font-size: 18px")
        self.btn_loc.clicked.connect(self.colocar)
        self.btn_loc.setEnabled(False)

        lbl_autoseg = QLabel("Auto-Segmentation")
        lbl_autoseg.setStyleSheet("font-size: 20px")
        #################################################################
        ##     Elementos del layout graficos
        #################################################################
        self.plot1 = pg.PlotWidget()
        self.plot1.setLabel('bottom', color='k', **{'font-size': '16pt'})
        self.plot1.getAxis('bottom').setPen(pg.mkPen(color='k', width=1))
        self.plot1.setLabel('left', color='k', **{'font-size': '16pt'})
        self.plot1.getAxis('left').setPen(pg.mkPen(color='k', width=1))
        self.plot1.showGrid(1, 1, 0.2)
        graficos.addWidget(self.plot1)
        #################################################################
        ##     Colocar elementos en layout botones
        #################################################################
        botones.addWidget(btnLoadSig)
        botones.addWidget(self.btnIniciar)
        results.addRow(txtnumseg, self.txtns)
        results.addRow(self.btnAdd)
        botones.addLayout(results)

        results2.addRow(lbl_autoseg)
        results2.addRow(lbl_umbral, self.txt_umbral)
        results2.addRow(lbl_basal, self.txt_basal)
        results2.addRow(lbl_ancho, self.txt_ancho)
        results2.addRow(lbl_separacion, self.txt_separacion)
        botones.addLayout(results2)
        botones.addWidget(self.btnauto)
        results3.addRow(lbl_total, self.txt_total)
        results3.addRow(lbl_file, self.seg_pos)
        results3.addRow(self.lbl_inicio, self.lbl_final)
        results3.addRow(self.btn_loc)
        botones.addLayout(results3)
        #################################################################
        ##     Colocar elementos en la ventana
        #################################################################
        bot = QWidget()
        bot.setLayout(botones)
        gra = QWidget()
        gra.setLayout(graficos)

        contain.addWidget(gra)
        contain.addWidget(bot)
        self.setCentralWidget(contain)
        self.show()
示例#5
0
    def MDFA(self):
        self.t_inicial = time()
        self.plot1.clear()
        qmax = int(self.txtQmax.text())
        qmin = int(self.txtQmin.text())
        dq = float(self.txtdQ.text())
        q = np.arange(qmin, qmax, dq)
        m = int(self.txtm.text())
        xn = np.arange(0, 135, 1)
        func = np.vectorize(lambda x: int(10.1 * math.exp(0.0866 * x)))
        n = func(xn)
        self.alphas = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        self.fespectros = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        self.qs = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        self.taus = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        self.hches = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        for i in range(len(self.rutas)):
            R = []
            self.y = np.asarray(
                pd.read_csv(self.rutas[i], sep='\t', header=None))
            val = len(self.y) / 4
            s = n[n < val]
            if (self.int_state == 0):
                Y = np.cumsum((self.y - np.mean(self.y)))
            elif (self.int_state == 1):
                Y = np.cumsum((self.y - np.mean(self.y)))
                Y = np.cumsum((Y - np.mean(Y)))
            YRev = Y
            N = len(Y)
            q = np.arange(qmin, qmax, dq)
            Fq = np.zeros((len(s), len(q)))
            znumb = np.where((q >= -0.1) & (q <= 0.1))[0][-1] - 1
            for ns in range(len(s)):
                Ns = int(N / s[ns])
                Var = np.zeros((Ns, len(q)))
                Varr = np.zeros((Ns, len(q)))
                for v in range(Ns):
                    SegNumb = np.arange(((v + 1) - 1) * s[ns], (v + 1) * s[ns])
                    Seg = Y[SegNumb]
                    SegRev = YRev[SegNumb]
                    poly = np.polyfit(SegNumb, Seg, m)
                    polyr = np.polyfit(SegNumb, SegRev, m)
                    fit = np.polyval(poly, SegNumb)
                    fitr = np.polyval(polyr, SegNumb)
                    myfunc(q, Var, Varr, v, Seg, fit, s, ns, SegRev, fitr)
                Var = np.transpose(Var)
                Varr = np.transpose(Varr)
                for nq in range(len(q)):
                    Fq[ns][nq] = pow(
                        (sum(Var[:][nq]) + sum(Varr[:][nq])) / (2 * Ns),
                        1 / q[nq])
                Fq[ns][znumb] = (Fq[ns][znumb - 1] + Fq[ns][znumb + 1]) / 2
                del (Var, Varr)
            logFq = np.log10(Fq)
            logFq = np.transpose(logFq)
            Hq = np.zeros(len(q))
            fes = []
            eses = []
            for nq in range(len(q)):
                f = np.transpose(logFq[:][nq])
                fes.append(f)
                eses.append(np.log10(s))
                P = np.polyfit(np.log10(s), logFq[:][nq], 1)
                if (self.int_state == 0):
                    Hq[nq] = P[0]
                elif (self.int_state == 1):
                    Hq[nq] = P[0] - 1
                ajuste = []
                for w in range(len(s)):
                    ajuste.append((Hq[nq] + 1) * np.log10(s[w]) + P[1])
                rcuadrada = round(r2_score(f, ajuste), 4)
                R.append(rcuadrada)
            # fes = pd.DataFrame(fes)
            # fes.to_csv(self.rutas[i]+'F(sq).txt', sep = '\t', index = False, header = None)
            # eses = pd.DataFrame(eses)
            # eses.to_csv(self.rutas[i]+'s.txt', sep = '\t', index = False, header = None)

            # ajustes = pd.DataFrame(R)
            # ajustes.to_csv(self.rutas[i]+'R_cuadrada.txt', sep = '\t', index = False, header = None)

            t = q * Hq - 1
            α = np.diff(t) / dq
            Hq = Hq[0:len(Hq) - 1]
            t = t[0:len(t) - 1]
            q = q[0:len(q) - 1]
            ####### α y f(α) #############################################
            fα = np.zeros(len(t))
            fα = q * α - t
            self.fα = fα
            self.α = α
            self.t = t
            self.Hq = Hq
            self.q = q
            self.btnMDFA.setEnabled(False)
            self.t_final = time()
            self.tiempo = round(float(self.t_final - self.t_inicial), 4)
            self.txttime.setText(str(self.tiempo))
            self.alphas[:][i] = self.α
            self.fespectros[:][i] = self.fα
            self.taus[:][i] = self.t
            self.hches[:][i] = self.Hq
            self.qs[:][i] = self.q
        self.list_MDFA.addItem('')
        for i in range(len(self.rutas)):
            names = str.split(self.rutas[i], "/")
            t = len(names)
            nombre = names[t - 1]
            self.list_MDFA.addItem(nombre)
        self.alphas = np.transpose(self.alphas)
        self.fespectros = np.transpose(self.fespectros)
        self.taus = np.transpose(self.taus)
        self.hches = np.transpose(self.hches)
        self.qs = np.transpose(self.qs)
        self.dialogo_done = Dialog('Done!!', 'Icons\listo.png')
        self.dialogo_done.show()
示例#6
0
class MDFA(QMainWindow):
    def __init__(self):
        super().__init__()
        self.initUI()
#%%

    def cargarSenial(self):
        self.aux = False
        self.list3.clear()
        self.list_MDFA.clear()
        self.plot1.clear()
        self.nombreSenial = QFileDialog.getOpenFileNames(
            None, 'Open file(s)', '/home')
        self.rutas = self.nombreSenial[0]

        self.dialog = Dialog(
            str(len(self.rutas)) + ' Files(s) loaded', 'open.png')
        self.dialog.show()
        self.list3.addItem('')
        for i in range(len(self.rutas)):
            names = str.split(self.rutas[i], "/")
            t = len(names)
            nombre = names[t - 1]
            self.list3.addItem(nombre)

        if (len(self.rutas) == 0):
            self.lbl_num_files.setStyleSheet("color : red; ")
            self.lbl_num_files.setText("Files loaded: " + str(len(self.rutas)))
        else:
            self.lbl_num_files.setStyleSheet("color : blue; ")
            self.lbl_num_files.setText("Files loaded: " + str(len(self.rutas)))
        self.aux = True
        self.btnMDFA.setEnabled(True)
#%%

    def plots(self):
        if (self.aux == True):
            self.plot1.clear()
            i = self.list3.currentIndex() - 1
            if (len(self.rutas) != 0):
                data = pd.read_csv(self.rutas[i], sep='\t', header=None)
                lineas = data.shape[1]
                if (lineas == 1):
                    self.y = np.asarray(data[0])
                elif (lineas == 2):
                    self.y = np.asarray(data[1])
                self.plot1.setLabel('bottom',
                                    color='k',
                                    **{'font-size': '14pt'})
                self.plot1.getAxis('bottom').setPen(
                    pg.mkPen(color='k', width=1))
                # Y1 axis
                self.plot1.setLabel('left', color='k', **{'font-size': '14pt'})
                self.plot1.getAxis('left').setPen(pg.mkPen(color='k', width=1))
                names = str.split(self.rutas[i], "/")
                t = len(names)
                nombre = names[t - 1]
                self.plot1.setTitle(nombre)
                self.plot1.plot(self.y, pen='k')
#%%

    def print_val(self):
        print(str(self.plots.checkedId()))

#%%

    def MDFA(self):
        self.t_inicial = time()
        self.plot1.clear()
        qmax = int(self.txtQmax.text())
        qmin = int(self.txtQmin.text())
        dq = float(self.txtdQ.text())
        q = np.arange(qmin, qmax, dq)
        m = int(self.txtm.text())
        xn = np.arange(0, 135, 1)
        func = np.vectorize(lambda x: int(10.1 * math.exp(0.0866 * x)))
        n = func(xn)
        self.alphas = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        self.fespectros = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        self.qs = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        self.taus = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        self.hches = np.transpose(np.zeros((len(q) - 1, len(self.rutas))))
        for i in range(len(self.rutas)):
            R = []
            self.y = np.asarray(
                pd.read_csv(self.rutas[i], sep='\t', header=None))
            val = len(self.y) / 4
            s = n[n < val]
            if (self.int_state == 0):
                Y = np.cumsum((self.y - np.mean(self.y)))
            elif (self.int_state == 1):
                Y = np.cumsum((self.y - np.mean(self.y)))
                Y = np.cumsum((Y - np.mean(Y)))
            YRev = Y
            N = len(Y)
            q = np.arange(qmin, qmax, dq)
            Fq = np.zeros((len(s), len(q)))
            znumb = np.where((q >= -0.1) & (q <= 0.1))[0][-1] - 1
            for ns in range(len(s)):
                Ns = int(N / s[ns])
                Var = np.zeros((Ns, len(q)))
                Varr = np.zeros((Ns, len(q)))
                for v in range(Ns):
                    SegNumb = np.arange(((v + 1) - 1) * s[ns], (v + 1) * s[ns])
                    Seg = Y[SegNumb]
                    SegRev = YRev[SegNumb]
                    poly = np.polyfit(SegNumb, Seg, m)
                    polyr = np.polyfit(SegNumb, SegRev, m)
                    fit = np.polyval(poly, SegNumb)
                    fitr = np.polyval(polyr, SegNumb)
                    myfunc(q, Var, Varr, v, Seg, fit, s, ns, SegRev, fitr)
                Var = np.transpose(Var)
                Varr = np.transpose(Varr)
                for nq in range(len(q)):
                    Fq[ns][nq] = pow(
                        (sum(Var[:][nq]) + sum(Varr[:][nq])) / (2 * Ns),
                        1 / q[nq])
                Fq[ns][znumb] = (Fq[ns][znumb - 1] + Fq[ns][znumb + 1]) / 2
                del (Var, Varr)
            logFq = np.log10(Fq)
            logFq = np.transpose(logFq)
            Hq = np.zeros(len(q))
            fes = []
            eses = []
            for nq in range(len(q)):
                f = np.transpose(logFq[:][nq])
                fes.append(f)
                eses.append(np.log10(s))
                P = np.polyfit(np.log10(s), logFq[:][nq], 1)
                if (self.int_state == 0):
                    Hq[nq] = P[0]
                elif (self.int_state == 1):
                    Hq[nq] = P[0] - 1
                ajuste = []
                for w in range(len(s)):
                    ajuste.append((Hq[nq] + 1) * np.log10(s[w]) + P[1])
                rcuadrada = round(r2_score(f, ajuste), 4)
                R.append(rcuadrada)
            # fes = pd.DataFrame(fes)
            # fes.to_csv(self.rutas[i]+'F(sq).txt', sep = '\t', index = False, header = None)
            # eses = pd.DataFrame(eses)
            # eses.to_csv(self.rutas[i]+'s.txt', sep = '\t', index = False, header = None)

            # ajustes = pd.DataFrame(R)
            # ajustes.to_csv(self.rutas[i]+'R_cuadrada.txt', sep = '\t', index = False, header = None)

            t = q * Hq - 1
            α = np.diff(t) / dq
            Hq = Hq[0:len(Hq) - 1]
            t = t[0:len(t) - 1]
            q = q[0:len(q) - 1]
            ####### α y f(α) #############################################
            fα = np.zeros(len(t))
            fα = q * α - t
            self.fα = fα
            self.α = α
            self.t = t
            self.Hq = Hq
            self.q = q
            self.btnMDFA.setEnabled(False)
            self.t_final = time()
            self.tiempo = round(float(self.t_final - self.t_inicial), 4)
            self.txttime.setText(str(self.tiempo))
            self.alphas[:][i] = self.α
            self.fespectros[:][i] = self.fα
            self.taus[:][i] = self.t
            self.hches[:][i] = self.Hq
            self.qs[:][i] = self.q
        self.list_MDFA.addItem('')
        for i in range(len(self.rutas)):
            names = str.split(self.rutas[i], "/")
            t = len(names)
            nombre = names[t - 1]
            self.list_MDFA.addItem(nombre)
        self.alphas = np.transpose(self.alphas)
        self.fespectros = np.transpose(self.fespectros)
        self.taus = np.transpose(self.taus)
        self.hches = np.transpose(self.hches)
        self.qs = np.transpose(self.qs)
        self.dialogo_done = Dialog('Done!!', 'Icons\listo.png')
        self.dialogo_done.show()
#%%

    def plots_MDFA(self):
        self.alphas2 = np.transpose(self.alphas)
        self.fespectros2 = np.transpose(self.fespectros)
        self.taus2 = np.transpose(self.taus)
        self.hches2 = np.transpose(self.hches)
        self.qs2 = np.transpose(self.qs)
        op = self.plots.checkedId()
        if (op == -2):
            if (self.aux == True):
                self.plot1.clear()
                i = self.list_MDFA.currentIndex() - 1
                if (len(self.rutas) != 0):
                    self.plot1.setLabel('bottom',
                                        'α',
                                        color='k',
                                        **{'font-size': '14pt'})
                    self.plot1.getAxis('bottom').setPen(
                        pg.mkPen(color='k', width=1))
                    # Y1 axis
                    self.plot1.setLabel('left',
                                        'f(α)',
                                        color='k',
                                        **{'font-size': '14pt'})
                    self.plot1.getAxis('left').setPen(
                        pg.mkPen(color='k', width=1))
                    names = str.split(self.rutas[i], "/")
                    t = len(names)
                    nombre = names[t - 1]
                    self.plot1.setTitle(nombre)
                    self.plot1.plot(self.alphas2[i],
                                    self.fespectros2[i],
                                    pen='r',
                                    symbol='o',
                                    symbolSize=10)
        elif (op == -3):
            if (self.aux == True):
                self.plot1.clear()
                i = self.list_MDFA.currentIndex() - 1
                if (len(self.rutas) != 0):
                    self.plot1.setLabel('bottom',
                                        'q',
                                        color='k',
                                        **{'font-size': '14pt'})
                    self.plot1.getAxis('bottom').setPen(
                        pg.mkPen(color='k', width=1))
                    # Y1 axis
                    self.plot1.setLabel('left',
                                        'τ(q)',
                                        color='k',
                                        **{'font-size': '14pt'})
                    self.plot1.getAxis('left').setPen(
                        pg.mkPen(color='k', width=1))
                    names = str.split(self.rutas[i], "/")
                    t = len(names)
                    nombre = names[t - 1]
                    self.plot1.setTitle(nombre)
                    self.plot1.plot(self.qs2[i],
                                    self.taus2[i],
                                    pen='r',
                                    symbol='o',
                                    symbolSize=10)

        elif (op == -4):
            if (self.aux == True):
                self.plot1.clear()
                i = self.list_MDFA.currentIndex() - 1
                if (len(self.rutas) != 0):
                    self.plot1.setLabel('bottom',
                                        'q',
                                        color='k',
                                        **{'font-size': '14pt'})
                    self.plot1.getAxis('bottom').setPen(
                        pg.mkPen(color='k', width=1))
                    self.plot1.setLabel('left',
                                        'h(q)',
                                        color='k',
                                        **{'font-size': '14pt'})
                    self.plot1.getAxis('left').setPen(
                        pg.mkPen(color='k', width=1))
                    names = str.split(self.rutas[i], "/")
                    t = len(names)
                    nombre = names[t - 1]
                    self.plot1.setTitle(nombre)
                    self.plot1.plot(self.qs2[i],
                                    self.hches2[i],
                                    pen='r',
                                    symbol='o',
                                    symbolSize=10)

#%%

    def saveFile(self):
        nom = QFileDialog.getSaveFileName(None, 'Saving Data in Current Plot')

        writer = pd.ExcelWriter(nom[0] + ".xlsx")

        a = pd.DataFrame(self.alphas)
        a.to_excel(writer, 'Atable', index=False, header=None)

        f = pd.DataFrame(self.fespectros)
        f.to_excel(writer, 'Ftable', index=False, header=None)

        t = pd.DataFrame(self.taus)
        t.to_excel(writer, 'Ttable', index=False, header=None)

        H = pd.DataFrame(self.hches)
        H.to_excel(writer, 'Htable', index=False, header=None)

        q = pd.DataFrame(self.qs)
        q.to_excel(writer, 'Qtable', index=False, header=None)

        writer.save()
#%%

    def state_check(self, state):
        if (state == Qt.Checked):
            self.int_state = 1
        else:
            self.int_state = 0
#%%

    def initUI(self):
        pg.setConfigOption('background', 'w')
        self.setWindowTitle('Multifractal Detrended Analysis Fluctuation')
        self.setWindowIcon(QIcon("Icons\multifractal.ico"))
        ########Variables Globales ####################################################
        ###############################################################################
        self.rutas = None
        self.nombreSenial = ''
        self.int_state = 0
        contain = QSplitter(Qt.Horizontal)
        botones = QVBoxLayout()
        graficos = QVBoxLayout()

        results1 = QFormLayout()
        results2 = QFormLayout()
        results3 = QFormLayout()
        group_box_files = QGroupBox("Load file(s)")
        group_box_settings = QGroupBox("Settings")
        group_box_plots = QGroupBox("Plots")
        #################################################################
        ##     Elementos del layout botones
        #################################################################
        font_size = 'font-size: 18px'

        self.btnLoadSig = QPushButton('Load signal')
        self.btnLoadSig.clicked.connect(self.cargarSenial)
        self.btnLoadSig.setStyleSheet(font_size)
        self.btnLoadSig.setEnabled(True)

        self.btnMDFA = QPushButton('MFDFA')
        self.btnMDFA.clicked.connect(self.MDFA)
        self.btnMDFA.setStyleSheet(font_size)
        self.btnMDFA.setEnabled(False)

        self.btnSavechar = QPushButton('Save data')
        self.btnSavechar.clicked.connect(self.saveFile)
        self.btnSavechar.setStyleSheet(font_size)

        self.txtQmax = QLineEdit('5')
        self.txtQmax.setEnabled(True)
        self.txtQmax.setStyleSheet(font_size)

        self.txtQmin = QLineEdit('-5')
        self.txtQmin.setEnabled(True)
        self.txtQmin.setStyleSheet(font_size)

        self.txtdQ = QLineEdit('0.1')
        self.txtdQ.setEnabled(True)
        self.txtdQ.setStyleSheet(font_size)

        self.txtm = QLineEdit('1')
        self.txtm.setEnabled(True)
        self.txtm.setStyleSheet(font_size)

        lbl_check1 = QLabel("Nonstationary ts:")
        lbl_check1.setStyleSheet(font_size)
        self.check1 = QCheckBox()
        self.check1.stateChanged.connect(self.state_check)

        self.lbl_num_files = QLabel("Files loaded: ")
        self.lbl_num_files.setStyleSheet(font_size)

        lbl_file = QLabel("File: ")
        lbl_file.setStyleSheet("font-size: 18px")
        self.list3 = QComboBox()
        self.list3.currentIndexChanged.connect(self.plots)

        self.lbltime = QLabel("Exe. time:")
        self.lbltime.setStyleSheet(font_size)
        self.txttime = QLabel("")
        self.txttime.setStyleSheet(font_size)

        b1 = QRadioButton("f(α) Vs α")
        b1.setStyleSheet(font_size)

        b2 = QRadioButton("τ(q) Vs q")
        b2.setStyleSheet(font_size)

        b3 = QRadioButton("h(q) Vs q")
        b3.setStyleSheet(font_size)

        self.plots = QButtonGroup()
        self.plots.addButton(b1)
        self.plots.addButton(b2)
        self.plots.addButton(b3)
        self.plots.exclusive()
        self.plots.buttonClicked.connect(self.print_val)

        lbl_MDFA = QLabel("File: ")
        lbl_MDFA.setStyleSheet(font_size)

        self.list_MDFA = QComboBox()
        self.list_MDFA.currentIndexChanged.connect(self.plots_MDFA)

        #################################################################
        ##     Elementos del layout graficos
        #################################################################
        self.plot1 = pg.PlotWidget()
        self.plot1.setLabel('bottom', " ", color='k', **{'font-size': '20pt'})
        self.plot1.getAxis('bottom').setPen(pg.mkPen(color='k', width=1))
        # Y1 axis
        self.plot1.setLabel('left', " ", color='k', **{'font-size': '20pt'})
        self.plot1.getAxis('left').setPen(pg.mkPen(color='k', width=1))
        self.plot1.showGrid(1, 1, 0.2)
        #################################################################
        ##     Colocar elementos en layout botones
        #################################################################
        results1.addRow(self.btnLoadSig)
        results1.addRow(self.lbl_num_files)
        results1.addRow(lbl_file, self.list3)
        group_box_files.setLayout(results1)

        results2.addRow(lbl_check1, self.check1)
        results2.addRow('Q+:', self.txtQmax)
        results2.addRow('Q-:', self.txtQmin)
        results2.addRow('dQ:', self.txtdQ)
        results2.addRow('m:', self.txtm)
        results2.addRow(self.lbltime, self.txttime)
        group_box_settings.setLayout(results2)

        results3.addRow(lbl_MDFA, self.list_MDFA)
        results3.addRow(b1)
        results3.addRow(b2)
        results3.addRow(b3)
        group_box_plots.setLayout(results3)

        botones.addWidget(group_box_files)
        botones.addWidget(group_box_settings)
        botones.addWidget(group_box_plots)

        botones.addWidget(self.btnMDFA)
        botones.addWidget(self.btnSavechar)
        #################################################################
        ##     Colocar elementos en layout graficos
        #################################################################
        graficos.addWidget(self.plot1)
        bot = QWidget()
        bot.setLayout(botones)
        gra = QWidget()
        gra.setLayout(graficos)
        contain.addWidget(bot)
        contain.addWidget(gra)
        self.setCentralWidget(contain)
示例#7
0
    def DFA1(self): 
        self.txth1.setEnabled(True)
        self.plot1.clear()
        self.list_DFA.clear()
        self.h = []
        self.fn = []
        self.s = []
        self.R = []
        order = int(self.txtm1.text())
        nombres_archivos = []
        
        
        for i in range(len(self.rutas)):
            data = read_csv(self.rutas[i], sep='\t', header = None )
            lineas= data.shape[1]
            if(lineas == 1):
                self.y1 = asarray(data[0])
            elif(lineas == 2):
                self.y1 = asarray(data[1])
            names = str.split(self.rutas[i],"/")
            t = len(names)
            nombre= names[t-1]
            names = str.split(self.rutas[i],nombre)
            nam   = str.split(nombre,'.')
  
            RUTA =  names[0] + '/DFA/'
            path = Path(RUTA)
            path.mkdir(parents = True,exist_ok = True)
            
            xn = arange(0, 135, 1)
            func = vectorize(lambda x: int(10.1*exp(0.0866 * x)))
            n = func(xn)
            self.s1 = []
            for j in range(len(n)):
                if(n[j]<=int(len(self.y1)/4)):
                    self.s1.append(n[j]) 
            self.fn1 = zeros(len(self.s1))
            for l in range(len(self.s1)):
                n_1= self.s1[l]
                N = len(self.y1)
                n = int(N/n_1)
                N1 = int(n_1*n)
                y = zeros((N))
                Yn = zeros((N))
                fitcoef = zeros((n,order+1))
                y = cumsum((self.y1-mean(self.y1)))
                x_aux = zeros(int(n_1))
                for i in range(int(n_1)):
                    x_aux[i] = i
                for j in range(n):
                    y_aux = y[int(j*n_1):int(j*n_1+n_1)]
                    fitcoef[j] = polyfit(x_aux,y_aux,order)
                for j in range(n):
                    Yn[int(j*n_1):int(j*n_1+n_1)] = polyval(fitcoef[j],x_aux)
                sum1    = sum(pow(transpose(y)-Yn,2))/N1
                self.fn1[l]   = sqrt(sum1)

            self.h1 = round(polyfit(log10(self.s1), log10(self.fn1),1)[0],4) 
            self.fn.append(log10(self.fn1))
            self.s.append(log10(self.s1))
            self.h.append(self.h1)
            
            plt.figure()
            plt.title(nam[0], fontsize = 15)
            plt.grid(True)
            plt.plot(self.y1)
            plt.savefig(RUTA + nam[0]+' Serie.png', dpi = 300)
            plt.close()
            
            
            datos = []
            datos.append(log10(self.s1))
            datos.append(log10(self.fn1))
            datos = transpose(asarray(datos))

            datos = DataFrame(datos)
            datos.to_csv(RUTA + nam[0]+' ln(F) vs ln(n).txt',header = None, index = False, sep='\t')
            rutaSave = RUTA
            nombres_archivos.append(nam[0]+':')
            
            if(len(self.rutas)!=0):
                ajuste = []
                b = polyfit(log10(self.s1), log10(self.fn1),1)[1]  
                for i in range(len(self.s1)):
                    ajuste.append(self.h1*log10(self.s1[i])+b)
                rcuadrada = round(r2_score(log10(self.fn1), ajuste),4)
                self.R.append(rcuadrada)
                
            plt.figure()
            plt.grid(True)
            plt.title(nam[0], fontsize = 15)
            plt.xlabel('Ln(n)', fontsize = 10)
            plt.ylabel('Ln(F(n))', fontsize = 10)
            plt.plot(log10(self.s1), log10(self.fn1), label = 'Original')
            plt.plot(log10(self.s1), ajuste, label = 'Adjust')
            plt.legend()
            plt.savefig(RUTA + nam[0]+' ln(F) vs ln(n).png', dpi = 300)
            plt.close()
            
        self.R = asarray(self.R) 
        self.h = asarray(self.h)
        self.list_DFA.addItem('')
        for i in range(len(self.rutas)):
            names=str.split(self.rutas[i],"/")
            t=len(names)
            nombre= names[t-1]
            self.list_DFA.addItem(nombre)
         
        datos_R = []
        datos_R.append(nombres_archivos) 
        datos_R.append(self.R)   
        datos_R = transpose(asarray(datos_R))
        datos_R = DataFrame(datos_R)
        datos_R.to_csv(rutaSave+'R^2.txt', header = None, index = False, sep = '\t')
        
        datos_h = []
        datos_h.append(nombres_archivos) 
        datos_h.append(self.h)   
        datos_h = transpose(asarray(datos_h))
        datos_h = DataFrame(datos_h)
        datos_h.to_csv(rutaSave+'Hurst Exponent.txt', header = None, index = False, sep = '\t')       
         
        self.dialog = Dialog('Done!!','Icons\listo.png')
        self.dialog.show()
示例#8
0
class DFA(QMainWindow):
    def __init__(self):      
        super(DFA,self).__init__()
        self.initUI()
#%%
    def cargarSenial1(self):
        self.aux = False
        self.list3.clear()
        self.plot1.clear()
        self.list_DFA.clear()
        self.txth1.clear()
        self.txtr1.clear()
        self.nombreSenial= QFileDialog.getOpenFileNames(None, 'Open file(s)', '/home')
        self.rutas = self.nombreSenial[0]
        
        self.dialog = Dialog(str(len(self.rutas))+' Files(s) loaded','open.png')
        self.dialog.show()
        self.list3.addItem('')
        for i in range(len(self.rutas)):
            names=str.split(self.rutas[i],"/")
            t=len(names)
            nombre= names[t-1]
            self.list3.addItem(nombre)
            
        if(len(self.rutas)==0):
            self.btnDFA1.setEnabled(False)
            self.lbl_num_files.setStyleSheet("color : red; ")
            self.lbl_num_files.setText("Files loaded: "+str(len(self.rutas)))
        else:
            self.lbl_num_files.setStyleSheet("color : blue; ")
            self.lbl_num_files.setText("Files loaded: "+str(len(self.rutas)))
        self.aux = True 
        self.btnDFA1.setEnabled(True)
        self.txtm1.setEnabled(True)
#%% 
    def DFA1(self): 
        self.txth1.setEnabled(True)
        self.plot1.clear()
        self.list_DFA.clear()
        self.h = []
        self.fn = []
        self.s = []
        self.R = []
        order = int(self.txtm1.text())
        nombres_archivos = []
        
        
        for i in range(len(self.rutas)):
            data = read_csv(self.rutas[i], sep='\t', header = None )
            lineas= data.shape[1]
            if(lineas == 1):
                self.y1 = asarray(data[0])
            elif(lineas == 2):
                self.y1 = asarray(data[1])
            names = str.split(self.rutas[i],"/")
            t = len(names)
            nombre= names[t-1]
            names = str.split(self.rutas[i],nombre)
            nam   = str.split(nombre,'.')
  
            RUTA =  names[0] + '/DFA/'
            path = Path(RUTA)
            path.mkdir(parents = True,exist_ok = True)
            
            xn = arange(0, 135, 1)
            func = vectorize(lambda x: int(10.1*exp(0.0866 * x)))
            n = func(xn)
            self.s1 = []
            for j in range(len(n)):
                if(n[j]<=int(len(self.y1)/4)):
                    self.s1.append(n[j]) 
            self.fn1 = zeros(len(self.s1))
            for l in range(len(self.s1)):
                n_1= self.s1[l]
                N = len(self.y1)
                n = int(N/n_1)
                N1 = int(n_1*n)
                y = zeros((N))
                Yn = zeros((N))
                fitcoef = zeros((n,order+1))
                y = cumsum((self.y1-mean(self.y1)))
                x_aux = zeros(int(n_1))
                for i in range(int(n_1)):
                    x_aux[i] = i
                for j in range(n):
                    y_aux = y[int(j*n_1):int(j*n_1+n_1)]
                    fitcoef[j] = polyfit(x_aux,y_aux,order)
                for j in range(n):
                    Yn[int(j*n_1):int(j*n_1+n_1)] = polyval(fitcoef[j],x_aux)
                sum1    = sum(pow(transpose(y)-Yn,2))/N1
                self.fn1[l]   = sqrt(sum1)

            self.h1 = round(polyfit(log10(self.s1), log10(self.fn1),1)[0],4) 
            self.fn.append(log10(self.fn1))
            self.s.append(log10(self.s1))
            self.h.append(self.h1)
            
            plt.figure()
            plt.title(nam[0], fontsize = 15)
            plt.grid(True)
            plt.plot(self.y1)
            plt.savefig(RUTA + nam[0]+' Serie.png', dpi = 300)
            plt.close()
            
            
            datos = []
            datos.append(log10(self.s1))
            datos.append(log10(self.fn1))
            datos = transpose(asarray(datos))

            datos = DataFrame(datos)
            datos.to_csv(RUTA + nam[0]+' ln(F) vs ln(n).txt',header = None, index = False, sep='\t')
            rutaSave = RUTA
            nombres_archivos.append(nam[0]+':')
            
            if(len(self.rutas)!=0):
                ajuste = []
                b = polyfit(log10(self.s1), log10(self.fn1),1)[1]  
                for i in range(len(self.s1)):
                    ajuste.append(self.h1*log10(self.s1[i])+b)
                rcuadrada = round(r2_score(log10(self.fn1), ajuste),4)
                self.R.append(rcuadrada)
                
            plt.figure()
            plt.grid(True)
            plt.title(nam[0], fontsize = 15)
            plt.xlabel('Ln(n)', fontsize = 10)
            plt.ylabel('Ln(F(n))', fontsize = 10)
            plt.plot(log10(self.s1), log10(self.fn1), label = 'Original')
            plt.plot(log10(self.s1), ajuste, label = 'Adjust')
            plt.legend()
            plt.savefig(RUTA + nam[0]+' ln(F) vs ln(n).png', dpi = 300)
            plt.close()
            
        self.R = asarray(self.R) 
        self.h = asarray(self.h)
        self.list_DFA.addItem('')
        for i in range(len(self.rutas)):
            names=str.split(self.rutas[i],"/")
            t=len(names)
            nombre= names[t-1]
            self.list_DFA.addItem(nombre)
         
        datos_R = []
        datos_R.append(nombres_archivos) 
        datos_R.append(self.R)   
        datos_R = transpose(asarray(datos_R))
        datos_R = DataFrame(datos_R)
        datos_R.to_csv(rutaSave+'R^2.txt', header = None, index = False, sep = '\t')
        
        datos_h = []
        datos_h.append(nombres_archivos) 
        datos_h.append(self.h)   
        datos_h = transpose(asarray(datos_h))
        datos_h = DataFrame(datos_h)
        datos_h.to_csv(rutaSave+'Hurst Exponent.txt', header = None, index = False, sep = '\t')       
         
        self.dialog = Dialog('Done!!','Icons\listo.png')
        self.dialog.show()
        
#%%
    def plots(self):
        if(self.aux == True):
            self.plot1.clear()
            i= self.list3.currentIndex()-1
            if(len(self.rutas)!=0):            
                data = read_csv(self.rutas[i],sep='\t', header=None)
                lineas= data.shape[1]
                if(lineas == 1):
                    self.y = asarray(data[0])
                elif(lineas == 2):
                    self.y = asarray(data[1])
                self.plot1.setLabel('bottom',color='k', **{'font-size':'14pt'})
                self.plot1.getAxis('bottom').setPen(pg.mkPen(color='k', width=1))
                # Y1 axis   
                self.plot1.setLabel('left',color='k', **{'font-size':'14pt'})
                self.plot1.getAxis('left').setPen(pg.mkPen(color='k', width=1))
                names=str.split(self.rutas[i],"/")
                t=len(names)
                nombre= names[t-1]
                self.plot1.setTitle(nombre)
                self.plot1.plot(self.y,pen='k')
                
#%%
    def plots_DFA(self):
        if(self.aux == True):
            self.plot1.clear()
            i= self.list_DFA.currentIndex()-1
            if(len(self.rutas)!=0):   
                self.plot1.setLabel('bottom',"ln(n)",color='k', **{'font-size':'14pt'})
                self.plot1.getAxis('bottom').setPen(pg.mkPen(color='k', width=1))
                # Y1 axis   
                self.plot1.setLabel('left',"ln(F(n))",color='k', **{'font-size':'14pt'})
                self.plot1.getAxis('left').setPen(pg.mkPen(color='k', width=1))
                names=str.split(self.rutas[i],"/")
                t=len(names)
                nombre= names[t-1]
                self.plot1.setTitle(nombre)
                self.plot1.plot(self.s[i],self.fn[i], symbol='o')
                self.txtr1.setText(str(self.R[i]))
                self.txth1.setText(str(self.h[i]))
        
#%% 
    def initUI(self):
        pg.setConfigOption('background', 'w')
        params = {
                'figure.figsize': [4, 4],
                'figure.dpi': 300,
                'savefig.dpi': 300
           }
        plt.rcParams.update(params)
###############################################################################
########Variables Globales ####################################################
############################################################################### 
        self.setWindowTitle('Detrended Analysis Fluctuation')
        self.setWindowIcon(QIcon("Icons\DFA.ico"))
        self.resize(1000, 600)
        self.ruta = None
        self.nombreSenial1=''
        self.x=[]
        self.y1=[]
        self.h1=[]

        contain   = QSplitter(Qt.Horizontal)
        botones   = QtWidgets.QVBoxLayout()
        graficos  = QVBoxLayout()
        results1  = QFormLayout()
        results2  = QFormLayout()
        results3  = QFormLayout()
        results4  = QFormLayout()
        group_box_files    = QGroupBox("Load file(s)")
        group_box_settings = QGroupBox("Settings")
        group_box_plots    = QGroupBox("Plots")
        group_box_values   = QGroupBox("Values")
        #################################################################
        ##     Elementos del layout botones
        #################################################################
        self.btnLoadSig1 = QPushButton('Load signal')
        self.btnLoadSig1.clicked.connect(self.cargarSenial1)
        self.btnLoadSig1.setStyleSheet("font-size: 18px")
        
        lblm1 = QLabel("P adjust degree: ")  
        lblm1.setStyleSheet("font-size: 18px")
        self.txtm1 = QLineEdit('1')
        self.txtm1.setEnabled(False)
        self.txtm1.setStyleSheet("font-size: 18px")
        
        lblh1 = QLabel("Hurst exponent h: ")
        lblh1.setStyleSheet("font-size: 18px")
        self.txth1 = QLineEdit('')
        self.txth1.setEnabled(False)
        
        lblr1 = QLabel("R^2: ")
        lblr1.setStyleSheet("font-size: 18px")
        self.txtr1 = QLabel('')
        
        self.lbl_num_files = QLabel("Files loaded: ")
        self.lbl_num_files.setStyleSheet("font-size: 18px")
             
        self.btnDFA1 = QPushButton('DFA')
        self.btnDFA1.clicked.connect(self.DFA1)
        self.btnDFA1.setStyleSheet("font-size: 18px")
        self.btnDFA1.setEnabled(False)
                      
        lbl_file = QLabel("File: ")
        lbl_file.setStyleSheet("font-size: 18px")
        
        self.list3 = QComboBox()
        self.list3.currentIndexChanged.connect(self.plots)
        
        lbl_DFA = QLabel("DFA: ")
        lbl_DFA.setStyleSheet("font-size: 18px")
        
        self.list_DFA = QComboBox()
        self.list_DFA.currentIndexChanged.connect(self.plots_DFA)
        
        #################################################################
        ##     Colocar elementos en layout botones
        #################################################################
        results1.addRow(self.btnLoadSig1)  
        results1.addRow(self.lbl_num_files)
        group_box_files.setLayout(results1)
        
        results2.addRow(lblm1, self.txtm1)
        group_box_settings.setLayout(results2)
        
        results3.addRow(lbl_file, self.list3)
        results3.addRow(lbl_DFA, self.list_DFA)
        group_box_plots.setLayout(results3)
        
        results4.addRow(lblh1, self.txth1)
        results4.addRow(lblr1, self.txtr1)
        group_box_values.setLayout(results4)
        
        botones.addWidget(group_box_files)
        botones.addWidget(group_box_settings)
        botones.addWidget(group_box_plots)
        botones.addWidget(group_box_values)
        botones.addWidget(self.btnDFA1)
        #################################################################
        ##     Colocar elementos en layout graficos
        #################################################################
        
        self.plot1=pg.PlotWidget()
        self.plot1.setLabel('bottom',color='k', **{'font-size':'14pt'})
        self.plot1.getAxis('bottom').setPen(pg.mkPen(color='k', width=1))
        self.plot1.setLabel('left',color='k', **{'font-size':'14pt'})
        self.plot1.getAxis('left').setPen(pg.mkPen(color='k', width=1))
        self.plot1.showGrid(1,1,0.2)
        graficos.addWidget(self.plot1)
        
        bot = QWidget()
        bot.setLayout(botones)
        gra = QWidget()
        gra.setLayout(graficos)
        
        contain.addWidget(bot)
        contain.addWidget(gra)
        self.setCentralWidget(contain)