import numpy as np from SimPEG.utils import mkvc, sdiag norm = np.linalg.norm class Problem(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! """ def __init__(self, mesh): self.mesh = mesh @property def RHS(self): """ Source matrix. """ return self._RHS @RHS.setter def RHS(self, value): self._RHS = value @property def P(self): """ Projection matrix. .. math:: d_\\text{pred} = Pu(m) """ return self._P @P.setter def P(self, value): self._P = value @property def std(self): """ Estimated Standard Deviations. """ return self._std @std.setter def std(self, value): self._std = value @property def dobs(self): """ Observed data. """ return self._dobs @dobs.setter def dobs(self, value): self._dobs = value def misfit(self, m, u=None): """ :param numpy.array m: geophysical model :param numpy.array u: fields :rtype: float :return: data misfit The data misfit: .. math:: \mu_\\text{data} = \mathbf{d}_\\text{pred} - \mathbf{d}_\\text{obs} Where P is a projection matrix that brings the field on the full domain to the data measurement locations; u is the field of interest; d_obs is the observed data. """ return self.dpred(m, u=u) - self.dobs 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. """ pass 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 Transpose of J """ pass def field(self, m): """ The field given the model. .. math:: u(m) """ pass def dpred(self, m, u=None): """ Predicted data. .. math:: d_\\text{pred} = Pu(m) """ if u is None: u = self.field(m) return self.P*u def modelTransform(self, m): """ :param numpy.array m: model :rtype: numpy.array :return: transformed model The modelTransform changes the model into the physical property. A common example of this is to invert for electrical conductivity in log space. In this case, your model will be log(sigma) and to get back to sigma, you can take the exponential: .. math:: m = \log{\sigma} \exp{m} = \exp{\log{\sigma}} = \sigma """ return np.exp(mkvc(m)) def modelTransformDeriv(self, m): """ :param numpy.array m: model :rtype: scipy.csr_matrix :return: derivative of transformed model The modelTransform changes the model into the physical property. The modelTransformDeriv provides the derivative of the modelTransform. If the model transform is: .. math:: m = \log{\sigma} \exp{m} = \exp{\log{\sigma}} = \sigma Then the derivative is: .. math:: \\frac{\partial \exp{m}}{\partial m} = \\text{sdiag}(\exp{m}) """ return sdiag(np.exp(mkvc(m))) class SyntheticProblem(object): """ Has helpful functions when dealing with synthetic problems To use this class, inherit to your problem:: class mySyntheticExample(Problem, SyntheticProblem): pass """ def createData(self, m, std=0.05): """ :param numpy.array m: geophysical model :param numpy.array std: standard deviation :rtype: numpy.array, numpy.array :return: dobs, Wd Create synthetic data given a model, and a standard deviation. 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. """ dobs = self.dpred(m) dobs = dobs noise = std*abs(dobs)*np.random.randn(*dobs.shape) dobs = dobs+noise eps = np.linalg.norm(mkvc(dobs),2)*1e-5 Wd = 1/(abs(dobs)*std+eps) return dobs, Wd