コード例 #1
0
    aPatch = lambda: coef.localizeCoefficient(patchT[TInd], aFine_ref)
    rPatch = lambda: coef.localizeCoefficient(patchT[TInd], a_Fine_to_be_approximated)

    epsCoarse = lod.computeErrorIndicatorCoarseFromCoefficients(patchT[TInd], csiT[TInd].muTPrime,  aPatch, rPatch)
    return epsCoarse



print('precomputing ....')

# Use mapper to distribute computations (mapper could be the 'map' built-in or e.g. an ipyparallel map)
patchT, correctorsListT, KmsijT, csiT = zip(*map(computeKmsij, range(world.NtCoarse)))
patchT, correctorRhsT, RmsiT = zip(*map(computeRmsi, range(world.NtCoarse)))


RFull = pglod.assemblePatchFunction(world, patchT, RmsiT)
MFull = fem.assemblePatchMatrix(world.NWorldFine, world.MLocFine)

print('computing error indicators')
epsCoarse = list(map(computeIndicators, range(world.NtCoarse)))

'''
Plot error indicator
'''
np_eps = np.einsum('i,i -> i', np.ones(np.size(epsCoarse)), epsCoarse)
draw_indicator(NWorldCoarse, np_eps, original_style=True, Gridsize=N)


Algorithm = algorithms.PercentageVsErrorAlgorithm(world = world,
                                                 k = k ,
                                                 boundaryConditions = boundaryConditions,
コード例 #2
0
    return E_vh, E_f, E_Rf



print('precomputing ....')

# Use mapper to distribute computations (mapper could be the 'map' built-in or e.g. an ipyparallel map)
print('computing real correctors',  end='', flush=True)
patchT, correctorsListT, KmsijT, csiT = zip(*map(real_computeKmsij, range(world.NtCoarse)))
print()
print('computing real right hand side correctors',  end='', flush=True)
patchT, correctorRhsT, RmsiT, cetaTPrimeT = zip(*map(real_computeRmsi, range(world.NtCoarse)))
print()

KFull = pglod.assembleMsStiffnessMatrix(world, patchT, KmsijT)
RFull = pglod.assemblePatchFunction(world, patchT, RmsiT)
MFull = fem.assemblePatchMatrix(world.NWorldFine, world.MLocFine)

Rf = pglod.assemblePatchFunction(world, patchT, correctorRhsT)

basis = fem.assembleProlongationMatrix(world.NWorldCoarse, world.NCoarseElement)

bFull = basis.T * MFull * f_trans - RFull

basisCorrectors = pglod.assembleBasisCorrectors(world, patchT, correctorsListT)
modifiedBasis = basis - basisCorrectors

uFull, _ = pglod.solve(world, KFull, bFull, boundaryConditions)

uLodFine = modifiedBasis * uFull
uLodFine += Rf
コード例 #3
0
    def StartAlgorithm(self):
        assert (self.init)  # only start the algorithm once

        # in case not every element is affected, the percentage would be missleading.
        eps_size = np.size(self.E_vh)
        self.E_vh = {
            i: self.E_vh[i]
            for i in range(np.size(self.E_vh)) if self.E_vh[i] > 0
        }

        full_percentage = len(self.E_vh) / eps_size

        world = self.world
        print('starting algorithm ...... ')

        TOLt = []
        to_be_updatedT = []
        energy_errorT = []
        rel_energy_errorT = []
        tmp_errorT = []

        offset = []
        TOL = 100  # not relevant

        for i in range(len(self.E_vh) + 1):
            if self.init:
                pass
            else:
                offset = self.UpdateNextElement(offset, Printing=False)

            if self.init:
                to_be_updated = np.size(offset) / len(self.E_vh) * 100
                to_be_updatedT.append(to_be_updated)
                pass
            else:
                to_be_updated = np.size(offset) / len(self.E_vh) * 100
                to_be_updatedT.append(to_be_updated * full_percentage)

            KFull = pglod.assembleMsStiffnessMatrix(world, self.patchT,
                                                    self.KmsijT)
            RFull = pglod.assemblePatchFunction(world, self.patchT,
                                                self.RmsijT)
            Rf = pglod.assemblePatchFunction(world, self.patchT,
                                             self.correctorsRhsT)

            basis = fem.assembleProlongationMatrix(world.NWorldCoarse,
                                                   world.NCoarseElement)

            bFull = basis.T * self.MFull * self.f_trans - RFull

            basisCorrectors = pglod.assembleBasisCorrectors(
                world, self.patchT, self.correctorsListT)
            modifiedBasis = basis - basisCorrectors

            uFull, _ = pglod.solve(world, KFull, bFull,
                                   self.boundaryConditions)

            uLodFine = modifiedBasis * uFull
            uLodFine += Rf

            uFineFull_trans_LOD = uLodFine

            if self.init:
                uFineFull_trans_LOD_old = uLodFine

            energy_norm = np.sqrt(
                np.dot(uFineFull_trans_LOD,
                       self.AFine_trans * uFineFull_trans_LOD))
            # tmp_error
            tmp_energy_error = np.sqrt(
                np.dot((uFineFull_trans_LOD - uFineFull_trans_LOD_old),
                       self.AFine_trans *
                       (uFineFull_trans_LOD - uFineFull_trans_LOD_old)))

            # actual error

            if self.compare_with_best_LOD:
                energy_error = np.sqrt(
                    np.dot((uFineFull_trans_LOD - self.u_best_LOD),
                           self.AFine_trans *
                           (uFineFull_trans_LOD - self.u_best_LOD)))
            else:
                energy_error = np.sqrt(
                    np.dot((uFineFull_trans_LOD - self.uFineFull_trans),
                           self.AFine_trans *
                           (uFineFull_trans_LOD - self.uFineFull_trans)))

            uFineFull_trans_LOD_old = uFineFull_trans_LOD

            if self.init:
                self.init = 0
                print(
                    ' step({:3d}/{})  T: {}  updates: {:7.3f}%, energy error: {:f}, tmp_error: {:f}, relative energy error: {:f}'
                    .format(i, len(self.E_vh), ' - ',
                            to_be_updated * full_percentage, energy_error,
                            tmp_energy_error, energy_error / energy_norm))
            else:
                print(
                    ' step({:3d}/{})  T: {:3d}  updates: {:7.3f}%, energy error: {:f}, tmp_error: {:f}, relative energy error: {:f}'
                    .format(i, len(self.E_vh), offset[-1],
                            to_be_updated * full_percentage, energy_error,
                            tmp_energy_error, energy_error / energy_norm))

            rel_energy_errorT.append(energy_error / energy_norm)
            energy_errorT.append(energy_error)
            tmp_errorT.append(tmp_energy_error)

        return to_be_updatedT, energy_errorT, tmp_errorT, rel_energy_errorT, TOLt, uFineFull_trans_LOD
コード例 #4
0
    def StartAlgorithm(self):
        assert (self.init)  # only start the algorithm once

        # in case not every element is affected, the percentage would be missleading.
        eps_size = np.size(self.E_vh)
        self.E_vh = {
            i: self.E_vh[i]
            for i in range(np.size(self.E_vh)) if self.E_vh[i] > 0
        }
        list = [v for v in self.E_vh.values()]
        list.append(0)
        tols = np.sort(list)[::-1]

        eps_size_f = np.size(self.E_vh)
        self.E_f = {
            i: self.E_f[i]
            for i in range(np.size(self.E_f)) if self.E_f[i] > 0
        }
        list_f = [v for v in self.E_f.values()]
        list_f.append(0)
        tols_f = np.sort(list)[::-1]

        # make sure we only update one element all the time
        for i in range(1, np.size(tols)):
            if tols[i] == tols[i - 1]:
                tols[i] -= 1e-7

        for i in range(1, np.size(tols_f)):
            if tols_f[i] == tols_f[i - 1]:
                tols_f[i] -= 1e-7

        full_percentage = len(self.E_vh) / eps_size
        full_percentage_f = len(self.E_f) / eps_size_f

        world = self.world
        print('starting algorithm ...... ')

        TOLt = []
        to_be_updatedT = []
        energy_errorT = []
        rel_energy_errorT = []
        tmp_errorT = []

        offset = []
        TOL = 100  # not relevant

        for i in range(np.size(tols)):
            if TOL == 0:
                pass
            else:
                TOL = tols[i]

            TOLt.append(TOL)
            offset = self.UpdateNextElement(TOL, offset, Printing=False)

            if self.init:
                to_be_updated = np.size(offset) / len(self.E_vh) * 100
                to_be_updatedT.append(to_be_updated)
                pass
            else:
                to_be_updated = np.size(offset) / len(self.E_vh) * 100
                to_be_updatedT.append(to_be_updated * full_percentage)

            KFull = pglod.assembleMsStiffnessMatrix(world, self.patchT,
                                                    self.KmsijT)
            RFull = pglod.assemblePatchFunction(world, self.patchT,
                                                self.RmsijT)
            Rf = pglod.assemblePatchFunction(world, self.patchT,
                                             self.correctorsRhsT)

            basis = fem.assembleProlongationMatrix(world.NWorldCoarse,
                                                   world.NCoarseElement)

            bFull = basis.T * self.MFull * self.f_trans - RFull

            basisCorrectors = pglod.assembleBasisCorrectors(
                world, self.patchT, self.correctorsListT)
            modifiedBasis = basis - basisCorrectors

            uFull, _ = pglod.solve(world, KFull, bFull,
                                   self.boundaryConditions)

            uLodFine = modifiedBasis * uFull
            uLodFine += Rf

            uFineFull_trans_LOD = uLodFine

            if self.init:
                self.init = 0
                uFineFull_trans_LOD_old = uLodFine

            energy_norm = np.sqrt(
                np.dot(uFineFull_trans_LOD,
                       self.AFine_trans * uFineFull_trans_LOD))
            # tmp_error
            tmp_energy_error = np.sqrt(
                np.dot((uFineFull_trans_LOD - uFineFull_trans_LOD_old),
                       self.AFine_trans *
                       (uFineFull_trans_LOD - uFineFull_trans_LOD_old)))

            # actual error
            if self.compare_with_best_LOD:
                energy_error = np.sqrt(
                    np.dot((uFineFull_trans_LOD - self.u_best_LOD),
                           self.AFine_trans *
                           (uFineFull_trans_LOD - self.u_best_LOD)))
            else:
                energy_error = np.sqrt(
                    np.dot((uFineFull_trans_LOD - self.uFineFull_trans),
                           self.AFine_trans *
                           (uFineFull_trans_LOD - self.uFineFull_trans)))

            uFineFull_trans_LOD_old = uFineFull_trans_LOD

            print(
                ' step({:3d}/{})    TOL: {:f}, updates: {:7.3f}%, energy error: {:f}, tmp_error: {:f}, relative energy error: {:f}'
                .format(i, np.size(tols), TOL, to_be_updated * full_percentage,
                        energy_error, tmp_energy_error,
                        energy_error / energy_norm))

            rel_energy_errorT.append(energy_error / energy_norm)
            energy_errorT.append(energy_error)
            tmp_errorT.append(tmp_energy_error)

            if TOL == 0:
                # stop now
                break

        return to_be_updatedT, energy_errorT, tmp_errorT, rel_energy_errorT, TOLt, uFineFull_trans_LOD
コード例 #5
0
    def StartAlgorithm(self):
        assert (self.init)  # only start the algorithm once

        # in case not every element is affected, the percentage would be missleading.
        eps_size = np.size(self.E_vh)
        self.E_vh = {
            i: self.E_vh[i]
            for i in range(np.size(self.E_vh)) if self.E_vh[i] > 0
        }
        full_percentage = len(self.E_vh) / eps_size

        world = self.world
        print('starting algorithm ...... ')

        TOL = self.StartingTolerance

        TOLt = []
        to_be_updatedT = []
        energy_errorT = []
        rel_energy_errorT = []
        tmp_errorT = []

        offset = []

        continue_computing = 1
        while continue_computing:
            TOLt.append(TOL)
            offset, computed = self.UpdateElements(TOL, offset, Printing=False)

            if computed:
                pass
            else:
                if self.init:
                    pass
                else:
                    to_be_updated = np.size(offset) / len(self.E_vh) * 100
                    to_be_updatedT.append(to_be_updated * full_percentage)

                    energy_errorT.append(energy_error)
                    tmp_errorT.append(old_tmp_energy_error)
                    if np.size(offset) / len(self.E_vh) == 1:
                        print('     every corrector has been updated')
                        continue_computing = 0
                        continue
                    else:
                        print('     skipping TOL {}'.format(TOL))
                        TOL *= 3 / 4.
                        continue

            to_be_updated = np.size(offset) / len(self.E_vh) * 100
            to_be_updatedT.append(to_be_updated * full_percentage)

            KFull = pglod.assembleMsStiffnessMatrix(world, self.patchT,
                                                    self.KmsijT)
            RFull = pglod.assemblePatchFunction(world, self.patchT,
                                                self.RmsijT)
            Rf = pglod.assemblePatchFunction(world, self.patchT,
                                             self.correctorsRhsT)

            basis = fem.assembleProlongationMatrix(world.NWorldCoarse,
                                                   world.NCoarseElement)

            bFull = basis.T * self.MFull * self.f_trans - RFull

            basisCorrectors = pglod.assembleBasisCorrectors(
                world, self.patchT, self.correctorsListT)
            modifiedBasis = basis - basisCorrectors

            uFull, _ = pglod.solve(world, KFull, bFull,
                                   self.boundaryConditions)

            uLodFine = modifiedBasis * uFull
            uLodFine += Rf

            uFineFull_trans_LOD = uLodFine

            if self.init:
                uFineFull_trans_LOD_old = uLodFine
                self.init = 0

            energy_norm = np.sqrt(
                np.dot(uFineFull_trans_LOD,
                       self.AFine_trans * uFineFull_trans_LOD))
            # tmp_error
            tmp_energy_error = np.sqrt(
                np.dot((uFineFull_trans_LOD - uFineFull_trans_LOD_old),
                       self.AFine_trans *
                       (uFineFull_trans_LOD - uFineFull_trans_LOD_old)))
            old_tmp_energy_error = tmp_energy_error

            # actual error
            energy_error = np.sqrt(
                np.dot((uFineFull_trans_LOD - self.uFineFull_trans),
                       self.AFine_trans *
                       (uFineFull_trans_LOD - self.uFineFull_trans)))

            uFineFull_trans_LOD_old = uFineFull_trans_LOD

            print(
                '             TOL: {:f}, updates: {:7.3f}%, energy error: {:f}, tmp_error: {:f}, relative energy error: {:f}'
                .format(TOL, to_be_updated * full_percentage, energy_error,
                        tmp_energy_error, energy_error / energy_norm))

            rel_energy_errorT.append(energy_error / energy_norm)
            energy_errorT.append(energy_error)
            tmp_errorT.append(tmp_energy_error)

            if tmp_energy_error > 1e-5:
                TOL *= 3 / 4.
            else:
                if int(np.size(offset) / len(self.E_vh)) == 1:
                    if computed:
                        print('     stop computing')
                        continue_computing = 0

        return to_be_updatedT, energy_errorT, tmp_errorT, rel_energy_errorT, TOLt, uFineFull_trans_LOD
            ]

            correctorRhs = lod.computeElementCorrector(patch, IPatch, aPatch,
                                                       None, MRhsList)[0]
            Rmsi = lod.computeRhsCoarseQuantities(patch, correctorRhs, aPatch)
            return patch, correctorRhs, Rmsi

        # Use mapper to distribute computations (mapper could be the 'map' built-in or e.g. an ipyparallel map)
        patchT, correctorsListT, KmsijT = zip(
            *map(computeKmsij, range(world.NtCoarse)))
        print('!')
        patchT, correctorRhsT, RmsiT = zip(
            *map(computeRmsi, range(world.NtCoarse)))
        print('!')
        KFull = pglod.assembleMsStiffnessMatrix(world, patchT, KmsijT)
        RFull = pglod.assemblePatchFunction(world, patchT, RmsiT)
        MFull = fem.assemblePatchMatrix(NFine, world.MLocFine)

        free = util.interiorpIndexMap(NWorldCoarse)
        basis = fem.assembleProlongationMatrix(NWorldCoarse, NCoarseElement)

        bFull = basis.T * MFull * f

        KFree = KFull[free][:, free]
        bFree = bFull[free]

        xFree = sparse.linalg.spsolve(KFree, bFree)

        basis = fem.assembleProlongationMatrix(NWorldCoarse, NCoarseElement)
        basisCorrectors = pglod.assembleBasisCorrectors(
            world, patchT, correctorsListT)