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simpeg/SimPEG/Problem.py
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from SimPEG import Utils, np, sp, Data
norm = np.linalg.norm
class BaseProblem(object):
"""
Problem is the base class for all geophysical forward problems in SimPEG.
The problem is a partial differential equation of the form:
.. math::
c(m, u) = 0
Here, m is the model and u is the field (or fields).
Given the model, m, we can calculate the fields u(m),
however, the data we collect is a subset of the fields,
and can be defined by a linear projection, P.
.. math::
d_\\text{pred} = Pu(m)
We are interested in how changing the model transforms the data,
as such we can take write the Taylor expansion:
.. math::
Pu(m + hv) = Pu(m) + hP\\frac{\partial u(m)}{\partial m} v + \mathcal{O}(h^2 \left\| v \\right\| )
We can linearize and define the sensitivity matrix as:
.. math::
J = P\\frac{\partial u}{\partial m}
The sensitivity matrix, and it's transpose will be used in the inverse problem
to (locally) find how model parameters change the data, and optimize!
"""
__metaclass__ = Utils.Save.Savable
counter = None #: A SimPEG.Utils.Counter object
dataPair = Data.BaseData
def __init__(self, mesh, model, *args, **kwargs):
Utils.setKwargs(self, **kwargs)
self.mesh = mesh
self.model = model
@Utils.timeIt
def J(self, m, v, u=None):
"""
:param numpy.array m: model
:param numpy.array v: vector to multiply
:param numpy.array u: fields
:rtype: numpy.array
:return: Jv
Working with the general PDE, c(m, u) = 0, where m is the model and u is the field,
the sensitivity is defined as:
.. math::
J = P\\frac{\partial u}{\partial m}
We can take the derivative of the PDE:
.. math::
\\nabla_m c(m, u) \delta m + \\nabla_u c(m, u) \delta u = 0
If the forward problem is invertible, then we can rearrange for du/dm:
.. math::
J = - P \left( \\nabla_u c(m, u) \\right)^{-1} \\nabla_m c(m, u)
This can often be computed given a vector (i.e. J(v)) rather than stored, as J is a large dense matrix.
"""
raise NotImplementedError('J is not yet implemented.')
@Utils.timeIt
def Jt(self, m, v, u=None):
"""
:param numpy.array m: model
:param numpy.array v: vector to multiply
:param numpy.array u: fields
:rtype: numpy.array
:return: JTv
Effect of transpose of J on a vector v.
"""
raise NotImplementedError('Jt is not yet implemented.')
@Utils.timeIt
def J_approx(self, m, v, u=None):
"""
:param numpy.array m: model
:param numpy.array v: vector to multiply
:param numpy.array u: fields
:rtype: numpy.array
:return: Jv
Approximate effect of J on a vector v
"""
return self.J(m, v, u)
@Utils.timeIt
def Jt_approx(self, m, v, u=None):
"""
:param numpy.array m: model
:param numpy.array v: vector to multiply
:param numpy.array u: fields
:rtype: numpy.array
:return: JTv
Approximate transpose of J*v
"""
return self.Jt(m, v, u)
def field(self, m):
"""
The field given the model.
.. math::
u(m)
"""
pass
def createSyntheticData(self, m, std=0.05, u=None):
"""
Create synthetic data given a model, and a standard deviation.
:param numpy.array m: geophysical model
:param numpy.array std: standard deviation
:rtype: numpy.array, numpy.array
:return: dobs, Wd
Returns the observed data with random Gaussian noise
and Wd which is the same size as data, and can be used to weight the inversion.
"""
dtrue = self.dpred(m,u=u)
noise = std*abs(dtrue)*np.random.randn(*dtrue.shape)
dobs = dtrue+noise
stdev = dobs*0 + std
return self.dataPair(dobs=dobs, std=stdev, dtrue=dtrue, mtrue=m)
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