def extrapolate(self):
# get well log
well_name = self.well_comboBox.currentText()
well = ppp.Well(str(CONF.well_dir / ".{}".format(well_name)))
log = well.get_log(str(self.log_comboBox.currentText()))
sm_log = well.get_log(str(self.sm_log_comboBox.currentText()))
# get a, b
a, b = float(self.a_lineEdit.text()), float(self.b_lineEdit.text())
shift = well.kelly_bushing + well.water_depth
shift_depth = np.array(log.depth)
mask = shift_depth >= shift
shift_depth = shift_depth[mask]
new_den = np.full_like(np.array(log.data), np.nan)
new_den[mask] = ppp.traugott(shift_depth, a, b)
old_den = np.array(sm_log.data)
old_mask = np.isfinite(old_den)
new_den[old_mask] = old_den[old_mask]
self.extraploated_log = ppp.Log()
self.extraploated_log.depth = sm_log.depth
self.extraploated_log.data = new_den
self.extraploated_log.units = sm_log.units
# self.fit_line_ax.append(self.ax.plot(new_den, log.depth)[0])
self.fit_line_ax2.append(self.ax2.plot(new_den, log.depth)[0])
self.matplotlib_widget.fig.canvas.draw()
def obp_button_on_clicked(self):
# get well log
well_name = self.well_comboBox.currentText()
well = ppp.Well(str(CONF.well_dir / ".{}".format(well_name)))
den_log = well.get_log(str(self.log_comboBox.currentText()))
depth = np.array(den_log.depth)
rho = np.array(den_log.data)
# insert missing density value with 2.4 g/cm3
mask = np.isnan(depth)
mask[den_log.start_idx:den_log.stop_idx] = True
mask_nan = np.isnan(rho)
mask = mask * mask_nan
rho[mask] = 2.4
kb = float(self.kb_lineEdit.text())
wd = float(self.wd_lineEdit.text())
rho_w = float(self.rho_lineEdit.text())
obp = ppp.overburden_pressure(depth,
rho,
kelly_bushing=kb,
depth_w=wd,
rho_w=rho_w)
self.obp_log = ppp.Log()
self.obp_log.depth = depth
self.obp_log.data = obp
self.ax2.cla()
self.ax2.plot(obp, depth)
self.ax2.plot(
ppp.hydrostatic_pressure(np.array(depth),
kelly_bushing=kb,
depth_w=wd,
rho_f=rho_w), depth, 'g--')
self.ax2.set_xlabel("Overburden Pressure (MPa)")
self.ax2.set_title("Overburden Pressure")
y = well.kelly_bushing + well.water_depth
self.ax2.axhline(y=y, color='brown')
self.ax2.annotate('KB+WD',
xy=(40, y),
xytext=(40, y + 500),
arrowprops=dict(facecolor='black',
shrink=0.05,
width=0.1,
headwidth=8))
self.matplotlib_widget.fig.canvas.draw()
def save_edit(self):
depth_tb = [float(self.tableWidget.item(irow, 0).text()) \
for irow in range(self.tableWidget.rowCount())]
data_tb = [float(self.tableWidget.item(irow, 1).text()) \
for irow in range(self.tableWidget.rowCount())]
temp_log = ppp.Log()
temp_log.depth = depth_tb
temp_log.data = data_tb
if temp_log != self.well_log:
reply = QMessageBox.question(
self, "Save",
"Log Data has been edited,\nAre you willing to save changes?",
QMessageBox.Yes, QMessageBox.Cancel)
if reply == QMessageBox.Yes:
self.well.update_log(self.current_log_name, temp_log)
self.well.save_well()
self.close()
def void_well_log():
return pygeopressure.Log()
def real_well_log():
return pygeopressure.Log("test/data/seudo_las.las")
def measured_log():
temp_log = pygeopressure.Log()
temp_log.depth = [4118.5]
temp_log.data = [60.605]
return temp_log
def measured_coef_log():
temp_log = pygeopressure.Log()
temp_log.depth = [4118.5]
temp_log.data = [1.5005]
return temp_log
