Exemple #1
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def test_BlochDecaySpectrum():
    # test-1
    m1 = BlochDecaySpectrum()

    dimension_dictionary_ = {
        "count": 1024,
        "spectral_width": "25000.0 Hz",
        "reference_offset": "0.0 Hz",
    }

    should_be = {
        "name": "BlochDecaySpectrum",
        "channels": ["1H"],
        "magnetic_flux_density": "9.4 T",
        "rotor_frequency": "0.0 Hz",
        "rotor_angle": "0.955316618 rad",
        "spectral_dimensions": [dimension_dictionary_],
    }
    dict_ = m1.json()
    assert Method.parse_dict_with_units(dict_) == m1

    dict_.pop("description")
    assert dict_ == should_be

    # test-2
    m2_dict = {
        "channels": ["29Si"],
        "magnetic_flux_density": "11.7 T",
        "rotor_angle": "90 deg",
        "spectral_dimensions": [{}],
    }
    m2 = BlochDecaySpectrum.parse_dict_with_units(m2_dict)

    angle = 90 * np.pi / 180
    dimension_dictionary_ = {
        "count": 1024,
        "spectral_width": "25000.0 Hz",
        "reference_offset": "0.0 Hz",
    }

    should_be = {
        "name": "BlochDecaySpectrum",
        "channels": ["29Si"],
        "magnetic_flux_density": "11.7 T",
        "rotor_frequency": "0.0 Hz",
        "rotor_angle": f"{angle} rad",
        "spectral_dimensions": [dimension_dictionary_],
    }

    dict_ = m2.json()
    assert Method.parse_dict_with_units(dict_) == m2

    dict_.pop("description")
    assert dict_ == should_be
Exemple #2
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def test_ST1_VAS_general():
    """Inner satellite-transition variable-angle spinning method"""
    mth = ST1_VAS(
        channels=["87Rb"],
        magnetic_flux_density=9.4,  # in T
        spectral_dimensions=[
            {
                "count": 1024,
                "spectral_width": 5e4,  # in Hz
                "reference_offset": 0,  # in Hz
            },
            {
                "count": 1024,
                "spectral_width": 5e4,  # in Hz
                "reference_offset": 0,  # in Hz
            },
        ],
    )
    assert mth.name == "ST1_VAS"

    des = (
        "Simulate a 1.5 -> 0.5 and -0.5 -> -1.5 satellite-transition variable-angle "
        "spinning spectrum.")
    assert mth.description == des
    assert mth.spectral_dimensions[0].events[
        0].transition_query == TransitionQuery(P={"channel-1": [[-1]]},
                                               D={"channel-1": [[2], [-2]]})
    assert mth.spectral_dimensions[1].events[
        0].transition_query == TransitionQuery(P={"channel-1": [[-1]]},
                                               D={"channel-1": [[0]]})
    assert Method.parse_dict_with_units(mth.json()) == mth
Exemple #3
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def test_SSB_general():
    """Inner satellite-transition variable-angle spinning method"""
    mth = SSB2D(
        channels=["87Rb"],
        magnetic_flux_density=9.4,  # in T
        rotor_frequency=1200,
        spectral_dimensions=[
            {
                "count": 1024,
                "spectral_width": 5e4,  # in Hz
                "reference_offset": 0,  # in Hz
            },
            {
                "count": 1024,
                "spectral_width": 5e4,  # in Hz
                "reference_offset": 0,  # in Hz
            },
        ],
    )
    assert mth.name == "SSB2D"

    assert mth.description == "Simulate a 2D sideband separation method."

    # test transition query
    tq = TransitionQuery(P={"channel-1": [[-1]]}, D={"channel-1": [[0]]})
    assert mth.spectral_dimensions[0].events[0].transition_query == tq
    assert mth.spectral_dimensions[1].events[0].transition_query == tq

    # test rotor_frequency
    assert mth.spectral_dimensions[0].events[0].rotor_frequency == 1200
    assert mth.spectral_dimensions[1].events[0].rotor_frequency == 1e9

    # check serialization
    assert Method.parse_dict_with_units(mth.json()) == mth
Exemple #4
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def test_04():
    """SAS method declaration"""
    mth = Method2D(
        channels=["87Rb"],
        magnetic_flux_density=9.4,  # in T
        rotor_angle=70.12 * np.pi / 180,
        spectral_dimensions=[
            {
                "count": 512,
                "spectral_width": 5e4,  # in Hz
                "events": [
                    {
                        "transition_query": {
                            "P": [-1],
                            "D": [0]
                        }
                    },
                ],
            },
            MAS_DIM.copy(),
        ],
    )

    assert mth.json() == TESTDATA["SAS"]
    assert Method.parse_dict_with_units(mth.json()) == mth
    assert Method2D.parse_dict_with_units(mth.json()) == mth
Exemple #5
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def test_05():
    """Satellite to central correlation method declaration"""
    sp0 = dict(
        count=512,
        spectral_width=5e6,
        events=[{
            "rotor_angle":
            0 * np.pi / 180,
            "transition_query": [{
                "P": [-1],
                "D": [2]
            }, {
                "P": [-1],
                "D": [-2]
            }],
        }],
    )
    mth = Method2D(
        channels=["87Rb"],
        magnetic_flux_density=9.4,  # in T
        spectral_dimensions=[sp0, MAS_DIM.copy()],
    )

    assert mth.json() == TESTDATA["STMAS"]
    assert Method.parse_dict_with_units(TESTDATA["STMAS"]) == mth
    assert Method2D.parse_dict_with_units(TESTDATA["STMAS"]) == mth
Exemple #6
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def test_methods():
    das = Method2D(
        channels=["87Rb"],
        magnetic_flux_density=4.2,  # in T
        rotor_angle=54.735 * 3.14159 / 180,  # in rads
        spectral_dimensions=[
            {
                "count":
                256,
                "spectral_width":
                2e4,  # in Hz
                "reference_offset":
                -5e3,  # in Hz
                "label":
                "70.12 dimension",
                "events": [
                    {
                        "fraction": 0.5,
                        "rotor_angle": 70.12 * 3.14159 / 180,  # in rads
                        "transition_query": [{
                            "ch1": {
                                "P": [-1],
                                "D": [0]
                            }
                        }],
                    },
                    {
                        "fraction": 0.5,
                        "rotor_angle": 30.12 * 3.14159 / 180,  # in rads
                        "transition_query": [{
                            "ch1": {
                                "P": [-1],
                                "D": [0]
                            }
                        }],
                    },
                ],
            },
            # The last spectral dimension block is the direct-dimension
            {
                "count": 256,
                "spectral_width": 3e4,  # in Hz
                "reference_offset": -7e3,  # in Hz
                "label": "MAS dimension",
                "events": [{
                    "transition_query": [{
                        "ch1": {
                            "P": [-1],
                            "D": [0]
                        }
                    }]
                }],
            },
        ],
    )

    assert das.affine_matrix is None
    assert das.json() == TESTDATA["DAS"]
    assert Method.parse_dict_with_units(das.json()) == das
    assert Method2D.parse_dict_with_units(das.json()) == das
Exemple #7
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def test_3Q_VAS_general():
    """3Q-VAS method test"""
    mth = ThreeQ_VAS(channels=["87Rb"], spectral_dimensions=[{}, {}])
    assert mth.name == "ThreeQ_VAS"
    assert mth.description == "Simulate a 3Q variable-angle spinning spectrum."
    assert mth.spectral_dimensions[0].events[
        0].transition_query == TransitionQuery(P={"channel-1": [[-3]]},
                                               D={"channel-1": [[0]]})
    assert mth.spectral_dimensions[1].events[
        0].transition_query == TransitionQuery(P={"channel-1": [[-1]]},
                                               D={"channel-1": [[0]]})
    assert Method.parse_dict_with_units(mth.json()) == mth
Exemple #8
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    def load_methods(self, filename: str):
        """Load a list of methods from the given JSON serialized file.

        Args:
            str filename: A local or remote address to a JSON serialized file.

        Example
        -------
        >>> sim.load_methods(filename) # doctest:+SKIP
        """
        contents = import_json(filename)
        self.methods = [Method.parse_dict_with_units(obj) for obj in contents]
Exemple #9
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def test_05():
    """Satellite to central correlation method declaration"""
    mth = Method2D(
        channels=["87Rb"],
        magnetic_flux_density=9.4,  # in T
        spectral_dimensions=[
            {
                "count":
                512,
                "spectral_width":
                5e6,  # in Hz
                "reference_offset":
                0,  # in Hz
                "events": [
                    {
                        "rotor_angle": 0 * np.pi / 180,
                        "transition_query": {
                            "P": [-1],
                            "D": [2, -2]
                        },
                    },
                ],
            },
            {
                "count":
                128,
                "spectral_width":
                5e4,  # in Hz
                "reference_offset":
                0,  # in Hz
                "events": [
                    {
                        "rotor_angle": 54.735 * np.pi / 180,
                        "transition_query": {
                            "P": [-1],
                            "D": [0]
                        },
                    },
                ],
            },
        ],
    )

    assert TESTDATA["STMAS"] == mth.json()
    assert Method.parse_dict_with_units(TESTDATA["STMAS"]) == mth
Exemple #10
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def test_method_2D():

    error = "The first element of the affine matrix cannot be zero."
    with pytest.raises(ValueError, match=f".*{error}.*"):
        Method2D(spectral_dimensions=[{}, {}], affine_matrix=[0, 1, 2, 3])

    # parse dict with units test
    dict_1d = {
        "channels": ["87Rb"],
        "magnetic_flux_density":
        "7 T",  # in T
        "rotor_angle":
        "54.735 deg",
        "spectral_dimensions": [
            {
                "spectral_width": "10 kHz",
                **sample_test_output
            },
            {
                "spectral_width": "10 kHz",
                **sample_test_output
            },
        ],
    }
    method1a = Method2D.parse_dict_with_units(dict_1d)
    assert Method.parse_dict_with_units(method1a.json()) == method1a

    method1b = Method2D(
        channels=["87Rb"],
        magnetic_flux_density=7,  # in T
        rotor_angle=54.735 * np.pi / 180,
        spectral_dimensions=[
            {
                "spectral_width": 1e4,
                **sample_test_output
            },
            {
                "spectral_width": 1e4,
                **sample_test_output
            },
        ],
    )

    assert method1a == method1b
Exemple #11
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def test_03():
    """generic method declaration"""
    mth = Method2D(
        channels=["87Rb"],
        magnetic_flux_density=9.4,  # in T
        spectral_dimensions=[
            {
                "count": 1024,
                "spectral_width": 5e4
            },
            {
                "count": 1024,
                "spectral_width": 5e4
            },
        ],
    )

    assert mth.json() == TESTDATA["generic"]
    assert Method.parse_dict_with_units(mth.json()) == mth
Exemple #12
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def test_3QMAS():
    """3Q MAS correlation method declaration"""
    mth = ThreeQ_VAS(
        channels=["87Rb"],
        magnetic_flux_density=9.4,  # in T
        spectral_dimensions=[
            {
                "count": 512,
                "spectral_width": 5e6,  # in Hz
                "reference_offset": 0,  # in Hz
            },
            {
                "count": 128,
                "spectral_width": 5e4,  # in Hz
                "reference_offset": 0,  # in Hz
            },
        ],
    )

    assert np.allclose(mth.affine_matrix, [0.5625, 0.4375, 0, 1])
    assert Method.parse_dict_with_units(mth.json()) == mth
Exemple #13
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def test_method_1D():
    error = "Expecting a 1x1 affine matrix."
    with pytest.raises(ValueError, match=f".*{error}.*"):
        Method1D(spectral_dimensions=[{}], affine_matrix=[1, 2, 3, 4])

    error = "Method requires exactly 1 spectral dimensions, given 2."
    with pytest.raises(ValueError, match=f".*{error}.*"):
        Method1D(spectral_dimensions=[{}, {}])

    # parse dict with units test
    dict_1d = {
        "channels": ["87Rb"],
        "magnetic_flux_density":
        "7 T",  # in T
        "rotor_angle":
        "54.735 deg",
        "rotor_frequency":
        "1e9 Hz",
        "spectral_dimensions": [{
            "spectral_width": "10 kHz",
            "reference_offset": "-4 kHz",
            **sample_test_output,
        }],
    }
    method1a = Method1D.parse_dict_with_units(dict_1d)
    assert Method.parse_dict_with_units(method1a.json()) == method1a

    method1b = Method1D(
        channels=["87Rb"],
        magnetic_flux_density=7,  # in T
        rotor_angle=54.735 * np.pi / 180,
        rotor_frequency=1e9,
        spectral_dimensions=[{
            "spectral_width": 1e4,
            "reference_offset": -4e3,
            **sample_test_output,
        }],
    )

    assert method1a == method1b
Exemple #14
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def test_03():
    """generic method declaration"""
    mth = Method(
        name="generic",
        channels=["87Rb"],
        magnetic_flux_density=9.4,  # in T
        rotor_frequency=1000000000000.0,
        spectral_dimensions=[
            {
                "count": 1024,
                "spectral_width": 5e4,
                "events": [sq_tq]
            },
            {
                "count": 1024,
                "spectral_width": 5e4,
                "events": [sq_tq]
            },
        ],
    )

    assert mth.json() == TESTDATA["generic"]
    assert Method.parse_dict_with_units(mth.json()) == mth
def test_method():
    # test-1 single dimension method

    # parse dict with units
    method_dictionary = {
        "name": "test-1-d",
        "description": "Test-1",
        "channels": ["29Si"],
        "magnetic_flux_density": "9.6 T",
        "rotor_frequency": "1 kHz",
        "rotor_angle": "54.735 deg",
        "spectral_dimensions": [dimension_dictionary],
    }
    the_method = Method.parse_dict_with_units(method_dictionary)
    basic_method_tests(the_method)

    # test-2 two dimensional two events method

    # parse dict with units
    dimension_dictionary["events"].append(event_dictionary)

    method_dictionary = {
        "name": "test-1-d",
        "description": "Test-1",
        "channels": ["29Si"],
        "magnetic_flux_density": "9.6 T",
        "rotor_frequency": "1 kHz",
        "rotor_angle": "54.735 deg",
        "spectral_dimensions": [dimension_dictionary, dimension_dictionary],
    }
    the_method = Method.parse_dict_with_units(method_dictionary)

    # test experiment assignment
    assert the_method.experiment is None

    with pytest.raises(ValidationError, match="Unable to read the data."):
        the_method.experiment = "test"

    data = np.random.rand(100).reshape(10, 10)
    csdm_data = cp.as_csdm(data)

    csdm_data.x[0] *= cp.ScalarQuantity("Hz")
    csdm_data.x[1] *= cp.ScalarQuantity("Hz")

    the_method.experiment = csdm_data
    the_method.simulation = csdm_data
    assert isinstance(the_method.experiment, cp.CSDM)
    assert isinstance(the_method.simulation, cp.CSDM)

    csdm_dict = csdm_data.to_dict()
    the_method.experiment = csdm_dict
    assert isinstance(the_method.experiment, cp.CSDM)
    assert the_method.experiment == csdm_data

    the_method.simulation = csdm_dict
    assert isinstance(the_method.simulation, cp.CSDM)
    assert the_method.simulation == csdm_data

    # json()
    event_dictionary_ = {
        "fraction": 0.5,
        "transition_query": [{
            "ch1": {
                "P": [-1]
            }
        }]
    }
    dimension_dictionary_ = {
        "count": 1024,
        "spectral_width": "100.0 Hz",
        "events": [event_dictionary_, event_dictionary_],
    }
    method_dictionary_ = {
        "name": "test-1-d",
        "description": "Test-1",
        "channels": ["29Si"],
        "magnetic_flux_density": "9.6 T",
        "rotor_frequency": "1000.0 Hz",
        "rotor_angle": "0.9553059660790962 rad",
        "spectral_dimensions": [dimension_dictionary_, dimension_dictionary_],
        "simulation": csdm_data.to_dict(),
        "experiment": csdm_data.to_dict(),
    }
    serialize = the_method.json()
    serialize["simulation"]["csdm"].pop("timestamp")
    assert serialize == method_dictionary_

    # json(units=False)
    event_dictionary_ = {
        "fraction": 0.5,
        "transition_query": [{
            "ch1": {
                "P": [-1]
            }
        }]
    }
    dimension_dictionary_ = {
        "count": 1024,
        "spectral_width": 100.0,
        "events": [event_dictionary_, event_dictionary_],
    }
    method_dictionary_ = {
        "name": "test-1-d",
        "description": "Test-1",
        "channels": ["29Si"],
        "magnetic_flux_density": 9.6,
        "rotor_frequency": 1000.0,
        "rotor_angle": 0.9553059660790962,
        "spectral_dimensions": [dimension_dictionary_, dimension_dictionary_],
        "simulation": csdm_data.to_dict(),
        "experiment": csdm_data.to_dict(),
    }
    serialize = the_method.json(units=False)
    serialize["simulation"]["csdm"].pop("timestamp")
    assert serialize == method_dictionary_
Exemple #16
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def test_method_1D():
    error = "Expecting a 1x1 affine matrix."
    with pytest.raises(ValueError, match=f".*{error}.*"):
        Method1D(spectral_dimensions=[{}], affine_matrix=[1, 2, 3, 4])

    error = r"The method allows 1 spectral dimension\(s\), 2 given."
    with pytest.raises(ValueError, match=f".*{error}.*"):
        Method1D(spectral_dimensions=[{}, {}])

    # parse dict with units test
    dict_1d = {
        "channels": ["87Rb"],
        "magnetic_flux_density":
        "7 T",  # in T
        "rotor_angle":
        "54.735 deg",
        "rotor_frequency":
        "1e9 Hz",
        "spectral_dimensions": [{
            "count":
            1024,
            "spectral_width":
            "10 kHz",  # in Hz
            "reference_offset":
            "-4 kHz",  # in Hz
            "events": [
                {
                    "fraction": 27 / 17,
                    "freq_contrib": ["Quad2_0"]
                },
                {
                    "fraction": 1,
                    "freq_contrib": ["Quad2_4"]
                },
            ],
        }],
    }
    method1a = Method1D.parse_dict_with_units(dict_1d)
    assert Method.parse_dict_with_units(method1a.json()) == method1a

    method1b = Method1D(
        channels=["87Rb"],
        magnetic_flux_density=7,  # in T
        rotor_angle=54.735 * np.pi / 180,
        rotor_frequency=1e9,
        spectral_dimensions=[{
            "count":
            1024,
            "spectral_width":
            1e4,  # in Hz
            "reference_offset":
            -4e3,  # in Hz
            "events": [
                {
                    "fraction": 27 / 17,
                    "freq_contrib": ["Quad2_0"]
                },
                {
                    "fraction": 1,
                    "freq_contrib": ["Quad2_4"]
                },
            ],
        }],
    )

    assert method1a == method1b
Exemple #17
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    def constructor(self, spectral_dimensions=[{}], **kwargs):
        # spectral_dimensions_root = deepcopy(spectral_dimensions)
        # kwargs_root = deepcopy(kwargs)
        parse = False
        if "parse" in kwargs:
            parse = kwargs["parse"]
            kwargs.pop("parse")

        local_template = deepcopy(template)
        spectral_dimensions = parse_spectral_dimensions(spectral_dimensions)
        prep = prepare_method_structure(local_template, **kwargs)
        global_events = local_template["global_event_attributes"]
        ge = set(global_events)
        kw = set(kwargs)
        common = kw.intersection(ge)

        if common != set():
            info = "`, `".join(list(common))
            e = f"`{info}` attribute cannot be modified for {prep['name']} method."
            raise AttributeError(e)

        dim = []
        n_sp = len(spectral_dimensions)
        n_tem = len(local_template["spectral_dimensions"])

        if n_tem < n_sp:
            raise ValueError(
                f"The method allows {n_tem} spectral dimension(s), {n_sp} given."
            )

        for i, s in enumerate(local_template["spectral_dimensions"]):
            events = []

            _fill_missing_events_in_template(spectral_dimensions[i], s)

            for j, e in enumerate(s["events"]):
                kw = deepcopy(kwargs)
                ge = deepcopy(global_events)

                # Remove `property_units` from default events instance.
                if "property_units" in e:
                    e.pop("property_units")

                if "events" in spectral_dimensions[i]:
                    kw.update(spectral_dimensions[i]["events"][j])

                e.update(kw)
                # prioritize the keyword arguments over the global arguments.
                ge.update(kw)
                e.update(ge)

                params = _fix_strings_in_events(e) if parse else Event(**e)
                events.append(params)

            if "events" in spectral_dimensions[i]:
                spectral_dimensions[i].pop("events")

            params = {**spectral_dimensions[i], "events": events}
            params = params if parse else SpectralDimension(**params)
            dim.append(params)

        method = {**prep, "spectral_dimensions": dim}
        method = Method.parse_dict_with_units(method) if parse else Method(**method)
        return method
Exemple #18
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    def parse_dict_with_units(cls, py_dict: dict):
        """Parse the physical quantity from a dictionary representation of the Simulator
        object, where the physical quantity is expressed as a string with a number and
        a unit.

        Args:
            dict py_dict: A required python dict object.

        Returns:
            A :ref:`simulator_api` object.

        Example
        -------

        >>> sim_py_dict = {
        ...     'config': {
        ...         'decompose_spectrum': 'none',
        ...         'integration_density': 70,
        ...         'integration_volume': 'octant',
        ...         'number_of_sidebands': 64
        ...     },
        ...     'spin_systems': [
        ...         {
        ...             'abundance': '100 %',
        ...             'sites': [{
        ...                 'isotope': '13C',
        ...                 'isotropic_chemical_shift': '20.0 ppm',
        ...                 'shielding_symmetric': {'eta': 0.5, 'zeta': '10.0 ppm'}
        ...             }]
        ...         },
        ...         {
        ...             'abundance': '100 %',
        ...             'sites': [{
        ...                 'isotope': '1H',
        ...                     'isotropic_chemical_shift': '-4.0 ppm',
        ...                     'shielding_symmetric': {'eta': 0.1, 'zeta': '2.1 ppm'}
        ...             }]
        ...         },
        ...         {
        ...             'abundance': '100 %',
        ...             'sites': [{
        ...                 'isotope': '27Al',
        ...                 'isotropic_chemical_shift': '120.0 ppm',
        ...                 'shielding_symmetric': {'eta': 0.1, 'zeta': '2.1 ppm'}
        ...             }]
        ...         }
        ...     ]
        ... }
        >>> sim = Simulator.parse_dict_with_units(sim_py_dict)
        >>> len(sim.spin_systems)
        3
        """
        py_copy_dict = deepcopy(py_dict)

        if "spin_systems" in py_copy_dict:
            spin_sys = py_copy_dict["spin_systems"]
            spin_sys = [SpinSystem.parse_dict_with_units(obj) for obj in spin_sys]
            py_copy_dict["spin_systems"] = spin_sys

        if "methods" in py_copy_dict:
            methods = py_copy_dict["methods"]
            methods = [Method.parse_dict_with_units(obj) for obj in methods]
            py_copy_dict["methods"] = methods

        return Simulator(**py_copy_dict)
Exemple #19
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def test_method():
    # test-1 single dimension method

    # parse dict with units
    event_dictionary = {
        "fraction": 0.5,
        "freq_contrib": freq_default,
        "magnetic_flux_density": "9.6 T",
        "rotor_frequency": "1 kHz",
        "rotor_angle": "54.735 deg",
    }
    dimension_dictionary = {
        "count": 1024,
        "spectral_width": "100 Hz",
        "reference_offset": "0 GHz",
        "events": [event_dictionary],
    }
    method_dictionary = {
        "name": "test-1-d",
        "description": "Test-1",
        "channels": ["29Si"],
        "spectral_dimensions": [dimension_dictionary],
    }
    the_method = Method.parse_dict_with_units(method_dictionary)
    basic_method_tests(the_method)

    # test-2 two dimensional two events method

    # parse dict with units
    event_dictionary = {
        "fraction": 0.5,
        "freq_contrib": freq_default,
        "magnetic_flux_density": "9.6 T",
        "rotor_frequency": "1 kHz",
        "rotor_angle": "54.735 deg",
    }
    dimension_dictionary = {
        "count": 1024,
        "spectral_width": "100 Hz",
        "reference_offset": "0 GHz",
        "events": [event_dictionary, event_dictionary],
    }
    method_dictionary = {
        "name": "test-1-d",
        "description": "Test-1",
        "channels": ["29Si"],
        "spectral_dimensions": [dimension_dictionary, dimension_dictionary],
    }
    the_method = Method.parse_dict_with_units(method_dictionary)

    # test experiment assignment
    assert the_method.experiment is None

    with pytest.raises(ValidationError, match="Unable to read the data."):
        the_method.experiment = "test"

    data = np.random.rand(100).reshape(10, 10)
    csdm_data = cp.as_csdm(data)

    csdm_data.dimensions[0] *= cp.ScalarQuantity("Hz")
    csdm_data.dimensions[1] *= cp.ScalarQuantity("Hz")
    the_method.experiment = csdm_data

    assert isinstance(the_method.experiment, cp.CSDM)

    csdm_dict = csdm_data.to_dict()
    the_method.experiment = csdm_dict
    assert isinstance(the_method.experiment, cp.CSDM)
    assert the_method.experiment == csdm_data

    # to_dict_with_unit()
    event_dictionary_ = {
        "fraction": 0.5,
        "transition_query": {
            "P": {
                "channel-1": [[-1.0]]
            }
        },
    }
    dimension_dictionary_ = {
        "count": 1024,
        "spectral_width": "100.0 Hz",
        "reference_offset": "0.0 Hz",
        "events": [event_dictionary_, event_dictionary_],
    }
    method_dictionary_ = {
        "name": "test-1-d",
        "description": "Test-1",
        "channels": ["29Si"],
        "magnetic_flux_density": "9.6 T",
        "rotor_frequency": "1000.0 Hz",
        "rotor_angle": "0.9553059660790962 rad",
        "spectral_dimensions": [dimension_dictionary_, dimension_dictionary_],
        "experiment": csdm_data.to_dict(),
    }
    assert the_method.json() == method_dictionary_

    # reduced_dict()
    event_dictionary_ = {
        "fraction": 0.5,
        "freq_contrib": freq_default,
        "magnetic_flux_density": 9.6,
        "rotor_frequency": 1000.0,
        "rotor_angle": 0.9553059660790962,
        "transition_query": {
            "P": {
                "channel-1": [[-1.0]]
            }
        },
    }
    dimension_dictionary_ = {
        "count": 1024,
        "spectral_width": 100.0,
        "reference_offset": 0.0,
        "events": [event_dictionary_, event_dictionary_],
    }
    method_dictionary_ = {
        "name": "test-1-d",
        "description": "Test-1",
        "channels": ["29Si"],
        "spectral_dimensions": [dimension_dictionary_, dimension_dictionary_],
        "experiment": csdm_data.to_dict(),
    }
    assert the_method.reduced_dict() == method_dictionary_

    # update_spectral_dimension_attributes_from_experiment
    the_method.update_spectral_dimension_attributes_from_experiment()
    for i in range(2):
        assert the_method.spectral_dimensions[i].count == 10
        assert the_method.spectral_dimensions[i].spectral_width == 10
        assert the_method.spectral_dimensions[i].reference_offset == 0
        assert the_method.spectral_dimensions[i].origin_offset == 0
Exemple #20
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def test_SSB_affine():
    mth = SSB2D(channels=["13C"], rotor_frequency=1200)
    np.allclose(mth.affine_matrix, [1, -1, 0, 0])
    assert Method.parse_dict_with_units(mth.json()) == mth