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pCDM.py
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pCDM.py
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'''
A pointCDM (pCDM) sub-class. Once we have the "finite" pCDM, this should end up being the parent pressure class
Written by T. Shreve, June 2019
'''
# Import Externals stuff
import numpy as np
from argparse import Namespace
# Personals
from . import pCDMfull
from .Pressure import Pressure
#sub-class pCDM
class pCDM(Pressure):
# ----------------------------------------------------------------------
# Initialize class
def __init__(self, name, x0=None, y0=None, z0=None, ax=None, ay=None, az=None, dip=None, strike=None, plunge=None, utmzone=None, ellps='WGS84', lon0=None, lat0=None, verbose=True):
'''
Sub-class implementing pCDM pressure objects.
Args:
* name : Name of the pressure source.
* utmzone : UTM zone (optional, default=None)
* ellps : ellipsoid (optional, default='WGS84')
Kwargs:
* x0, y0 : Center of pressure source in lat/lon or utm
* z0 : Depth
* ax, ay, az : None for pCDM
* dip : Clockwise around N-S (Y) axis; dip = 90 means vertically elongated source
* strike : Clockwise from N; strike = 0 means source is oriented N-S
* plunge : Clockwise along E-W (X) axis
* ellps : ellipsoid (optional, default='WGS84')
'''
# Attribute only for pCDM and CDM
self.deltapotency = None
# Unit potency based on semi-axes
self.DVtot = None
self.DVx = None
self.DVy = None
self.DVz = None
self.A = None
self.B = None
self.scale = 1000000
# Base class init
super(pCDM,self).__init__(name, x0=x0, y0=y0, z0=z0, ax=ax, ay=ay, az=az, dip=dip, strike=strike, plunge=plunge, utmzone=utmzone, ellps=ellps, lon0=lon0, lat0=lat0, verbose=True)
self.source = "pCDM"
if None not in {x0, y0, z0, dip, strike, plunge}:
self.createShape(x0, y0, z0, dip, strike, plunge)
print("Defining source parameters")
return
# ----------------------------------------------------------------------
# ----------------------------------------------------------------------
# Find unit potency change (opening=1)
def computeTotalpotency(self):
'''
Computes the total potency and ratios A and B
Args:
* A : Ratio of horizontal potency (volume) to total potency (volume) variation
* B : Ratio of vertical potency (volume) variation
* self.DV : Change in potency
'''
if None in {self.DVz, self.DVx, self.DVy}:
self.DVz = self.ellipshape['az']
self.DVy = self.ellipshape['ay']
self.DVx = self.ellipshape['ax']
self.A = self.DVz/(self.DVz+self.DVy+self.DVx)
self.B = self.DVy/(self.DVy+self.DVx)
self.DVtot = (self.DVz+self.DVy+self.DVx)
return
# ----------------------------------------------------------------------
# ----------------------------------------------------------------------
# ----------------------------------------------------------------------
# Some building routines that can be touched... I guess
# ----------------------------------------------------------------------
# ----------------------------------------------------------------------
# ----------------------------------------------------------------------
def pressure2dis(self, data, delta="volume", volume=None):
'''
Computes the surface displacement at the data location using pCDM. ~~~ This is where the good stuff happens ~~
Args:
* data : data object from gps or insar.
* delta : only total potency, in units of volume, in the pCDM case
Returns:
* u : x, y, and z displacements
'''
# Get parameters
if self.ellipshape is None:
raise Exception("Error: Need to define shape of source (run self.createShape)")
#define dictionary entries as variables
ellipse = Namespace(**self.ellipshape)
# Set the volume change
if volume is None:
DVx = ellipse.ax
DVy = ellipse.ay
DVz = ellipse.az
self.computeTotalpotency()
else:
# Set the potency value
if delta=="volume":
DVx, DVy, DVz = self.scale, self.scale, self.scale
if delta=="pressure":
raise Exception("pCDM requires potencies, not pressure")
# Set poisson's ratio
if self.nu is None:
self.nu = 0.25
# Get data position -- in m
x = data.x*1000
y = data.y*1000
z = np.zeros(x.shape) # Data are at the surface
# Run it for pCDM pressure source
# Convert from dip, strike, and plunge to omegaX, omegaY, omegaZ - verify they have same convention as Yang
omegaX = ellipse.plunge
omegaY = 90. - ellipse.dip
omegaZ = ellipse.strike
if any(v != 0.0 for v in [DVx, DVy, DVz]):
#### x0, y0 need to be in utm and meters
Ux1, Ux2, Ux3, Uy1, Uy2, Uy3, Uz1, Uz2, Uz3, Ux, Uy, Uz = pCDMfull.displacement(x, y, z, ellipse.x0m*1000, ellipse.y0m*1000, ellipse.z0, omegaX, omegaY, omegaZ, DVx, DVy, DVz, self.nu)
else:
u1 = np.zeros((len(x), 3))
u2 = np.zeros((len(x), 3))
u3 = np.zeros((len(x), 3))
# All done
# concatenate into one array
u1 = np.vstack([Ux1, Uy1, Uz1]).T
u2 = np.vstack([Ux2, Uy2, Uz2]).T
u3 = np.vstack([Ux3, Uy3, Uz3]).T
return u1, u2, u3
# ----------------------------------------------------------------------
# Define the shape of the CDM
#
# ----------------------------------------------------------------------
def createShape(self, x, y, z0, dip, strike, plunge, latlon=True):
""""
Defines the shape of the pCDM pressure source.
Args:
* x0, y0 : Center of pressure source in lat/lon or utm
* z0 : Depth
* A : Horizontal divided by total volume variation ratio, A = DVz/(DVx+DVy+DVz) --- ??? or potency ???
* B : Vertical volume variation ratio, B : DVy/(DVx+DVy) --- ??? or potency ???
* dip : Clockwise around N-S (Y) axis ??? To verify
* strike : Clockwise from N ??? To verify
* plunge : Clockwise along E-W (X) axis??? To verify
Examples:
A = 1, any B : horizontal sill
A = 0, B = 0.5 : vertical pipe
A = 0, B = 0 or 1 : vertical dyke
A = 1/3, B = 0.5 : isotrope source
A > 0, B > 0 : dyke + sill
"""
if latlon is True:
self.lon, self.lat = x, y
lon1, lat1 = x, y
self.pressure2xy()
x1, y1 = self.xf, self.yf
else:
self.xf, self.yf = x, y
x1, y1 = x, y
self.pressure2ll()
lon1, lat1 = self.lon, self.lat
##c, b, a = np.sort([float(ax),float(ay),float(az)])
##if b == c:
## if a == b == c:
## raise Exception('All axes are equal, use Mogi.py')
## else:
## raise Exception('Semi-minor axes are equal, use Yang.py')
#A, B, self.DV = self.computePotency()
# DVx = 4*ay*az #unit potency (assume opening = 1 m )
# DVy = 4*ax*az
# DVz = 4*ax*ay
# A = DVz / (DVx + DVy + DVz)
# B = DVy / (DVx + DVy)
# self.DV = (DVx + DVy + DVz)
self.ellipshape = {'x0': lon1,'x0m': x1,'y0': lat1, 'y0m': y1,'z0': z0, 'ax': 1.0, 'ay': 1.0, 'az': 1.0,'dip': dip, 'strike': strike, 'plunge': plunge}
return