Ejemplo n.º 1
0
    def scan(self,
             scan: AbstractScan,
             detectors: Union[AbstractDetector, Sequence[AbstractDetector]],
             potential: Union[Atoms, AbstractPotential],
             max_batch: int = 1,
             pbar: bool = True) -> dict:
        """
        Raster scan the probe across the potential and record a measurement for each detector.

        :param scan: Scan object defining the positions of the probe wave functions.
        :param detectors: The detectors recording the measurements.
        :param potential: The potential across which to scan the probe .
        :param max_batch: The probe batch size. Larger batches are faster, but require more memory.
        :param pbar: If true, display progress bars.
        :return: Dictionary of measurements with keys given by the detector.
        """

        self.grid.match(potential.grid)
        self.grid.check_is_defined()

        if isinstance(detectors, AbstractDetector):
            detectors = [detectors]

        measurements = {}
        for detector in detectors:
            measurements[detector] = detector.allocate_measurement(
                self.grid, self.wavelength, scan)

        scan_bar = ProgressBar(total=len(scan), desc='Scan', disable=not pbar)

        if isinstance(potential, AbstractTDSPotentialBuilder):
            probe_generators = self._generate_tds_probes(
                scan, potential, max_batch, pbar)
        else:
            if isinstance(potential, AbstractPotentialBuilder):
                potential = potential.build(pbar=True)

            probe_generators = [
                self._generate_probes(scan, potential, max_batch)
            ]

        for probe_generator in probe_generators:
            scan_bar.reset()
            for start, end, exit_probes in probe_generator:
                for detector, measurement in measurements.items():
                    scan.insert_new_measurement(measurement, start, end,
                                                detector.detect(exit_probes))

                scan_bar.update(end - start)

            scan_bar.refresh()

        scan_bar.close()

        return measurements
Ejemplo n.º 2
0
    def get_transition_potentials(self,
                                  extent: Union[float, Sequence[float]] = None,
                                  gpts: Union[float, Sequence[float]] = None,
                                  sampling: Union[float,
                                                  Sequence[float]] = None,
                                  energy: float = None,
                                  pbar=True):

        transitions = []
        if isinstance(pbar, bool):
            pbar = ProgressBar(total=len(self),
                               desc='Transitions',
                               disable=(not pbar))

        _, bound_wave = self._calculate_bound()
        _, continuum_waves = self._calculate_continuum()
        energy_loss = self.energy_loss

        bound_wave = interp1d(*bound_wave,
                              kind='cubic',
                              fill_value='extrapolate',
                              bounds_error=False)

        for bound_state, continuum_state in self.get_transition_quantum_numbers(
        ):
            continuum_wave = continuum_waves[continuum_state[0]]

            continuum_wave = interp1d(*continuum_wave,
                                      kind='cubic',
                                      fill_value='extrapolate',
                                      bounds_error=False)

            transition = ProjectedAtomicTransition(
                Z=self.Z,
                bound_wave=bound_wave,
                continuum_wave=continuum_wave,
                bound_state=bound_state,
                continuum_state=continuum_state,
                energy_loss=energy_loss,
                extent=extent,
                gpts=gpts,
                sampling=sampling,
                energy=energy)
            transitions += [transition]
            pbar.update(1)

        pbar.refresh()
        pbar.close()
        return transitions
Ejemplo n.º 3
0
    def _generate_tds_probes(self, scan, potential, max_batch, pbar):
        tds_bar = ProgressBar(total=len(potential.frozen_phonons),
                              desc='TDS',
                              disable=(not pbar)
                              or (len(potential.frozen_phonons) == 1))
        potential_pbar = ProgressBar(total=len(potential),
                                     desc='Potential',
                                     disable=not pbar)

        for potential_config in potential.generate_frozen_phonon_potentials(
                pbar=potential_pbar):
            yield self._generate_probes(scan, potential_config, max_batch)
            tds_bar.update(1)

        potential_pbar.close()
        tds_bar.refresh()
        tds_bar.close()
Ejemplo n.º 4
0
    def _generate_partial(self, max_batch: int = None, pbar: bool = True):
        if max_batch is None:
            n_batches = 1
        else:
            n_batches = (len(self) + (-len(self) % max_batch)) // max_batch

        batch_pbar = ProgressBar(total=len(self),
                                 desc='Batches',
                                 disable=(not pbar) or (n_batches == 1))
        batch_sizes = split_integer(len(self), n_batches)
        N = 0
        for batch_size in batch_sizes:
            yield PartialSMatrix(N, N + batch_size, self)
            N += batch_size
            batch_pbar.update(batch_size)

        batch_pbar.refresh()
        batch_pbar.close()
Ejemplo n.º 5
0
    def scan(self,
             potential: Union[Atoms, AbstractPotential],
             scan: AbstractScan,
             detectors: Sequence[AbstractDetector],
             max_batch_probes: int = 1,
             max_batch_expansion: int = None,
             pbar: bool = True):

        self.grid.match(potential.grid)
        self.grid.check_is_defined()

        measurements = {}
        for detector in detectors:
            measurements[detector] = detector.allocate_measurement(
                self.interpolated_grid, self.wavelength, scan)

        if isinstance(potential, AbstractTDSPotentialBuilder):
            probe_generators = self._generate_tds_probes(
                scan,
                potential,
                max_batch_probes=max_batch_probes,
                max_batch_expansion=max_batch_expansion,
                potential_pbar=pbar,
                multislice_pbar=pbar)
        else:
            if isinstance(potential, AbstractPotentialBuilder):
                potential = potential.build(pbar=True)

            S = self.multislice(potential,
                                max_batch=max_batch_probes,
                                pbar=pbar)
            probe_generators = [
                S._generate_probes(scan, max_batch_probes, max_batch_expansion)
            ]

        tds_bar = ProgressBar(total=len(potential.frozen_phonons),
                              desc='TDS',
                              disable=(not pbar)
                              or (len(potential.frozen_phonons) == 1))

        scan_bar = ProgressBar(total=len(scan), desc='Scan', disable=not pbar)

        for probe_generator in probe_generators:
            scan_bar.reset()

            for start, end, exit_probes in probe_generator:
                for detector, measurement in measurements.items():
                    scan.insert_new_measurement(measurement, start, end,
                                                detector.detect(exit_probes))

                scan_bar.update(end - start)

            scan_bar.refresh()
            tds_bar.update(1)

        scan_bar.close()

        tds_bar.refresh()
        tds_bar.close()

        return measurements