Esempio n. 1
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    def test_diffusion(self):
        model = sycomore.como.Model(
            sycomore.Species(0 * Hz, 0 * Hz, 1 * um * um / ms),
            sycomore.Magnetization(0, 0, 1),
            [["foo", sycomore.TimeInterval(500 * ms, 0.1 * rad / um)]])

        model.apply_pulse(sycomore.Pulse(40 * deg, 0 * deg))
        model.apply_time_interval("foo")

        grid = model.magnetization()
        for index, _ in sycomore.GridScanner(grid.origin(), grid.shape()):
            if index == sycomore.Index(-1):
                self.assertEqual(grid[index].p, 0)
                self.assertEqual(grid[index].z, 0)
                self.assertAlmostEqual(grid[index].m, 0 + 0.003062528150606j)
            elif index == sycomore.Index(0):
                self.assertEqual(grid[index].p, 0)
                self.assertAlmostEqual(grid[index].z, 0.766044443118978)
                self.assertEqual(grid[index].m, 0)
            elif index == sycomore.Index(1):
                self.assertAlmostEqual(grid[index].p, 0 - 0.003062528150606j)
                self.assertEqual(grid[index].z, 0)
                self.assertEqual(grid[index].m, 0)
            else:
                self.assertEqual(grid[index].p, 0)
                self.assertAlmostEqual(grid[index].z, 0)
                self.assertAlmostEqual(grid[index].m, 0)
Esempio n. 2
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    def setUp(self):
        self.species = sycomore.Species(1000*ms, 100*ms, 0.89*um*um/ms)
        self.m0 = sycomore.Magnetization(0, 0, 1)

        self.flip_angle = 40*deg
        self.pulse_duration = 1*ms
        self.pulse_support_size = 101
        self.zero_crossings = 2

        self.TR = 500*ms
        self.slice_thickness = 1*mm

        self.TR_count = 10
Esempio n. 3
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    def test_off_resonance(self):
        species = sycomore.Species(0 * Hz, 0 * Hz, 0 * um * um / ms)
        m0 = sycomore.Magnetization(0, 0, 1)

        pulse = sycomore.Pulse(90 * deg, math.pi * rad)
        pulse_duration = 1 * ms
        pulse_support_size = 101
        zero_crossings = 2

        # NOTE: in the absence of relaxation and diffusion, the TR is meaningless
        TR = 500 * ms
        slice_thickness = 1 * mm

        t0 = pulse_duration / (2 * zero_crossings)
        sinc_pulse = sycomore.HardPulseApproximation(
            pulse, sycomore.linspace(pulse_duration, pulse_support_size),
            sycomore.sinc_envelope(t0), 1 / t0, slice_thickness, "rf")

        refocalization = sycomore.TimeInterval(
            (TR - pulse_duration) / 2., -sinc_pulse.get_gradient_moment() / 2)

        model = sycomore.como.Model(
            species, m0, [["rf", sinc_pulse.get_time_interval()],
                          ["refocalization", refocalization]])

        model.apply_pulse(sinc_pulse)
        model.apply_time_interval("refocalization")

        frequencies = sycomore.linspace(60. * rad / ms, 201)
        magnetization = [
            model.isochromat(set(), sycomore.Point(), f) for f in frequencies
        ]

        root = os.environ["SYCOMORE_TEST_DATA"]
        with open(os.path.join(root, "baseline", "off_resonance.dat"),
                  "rb") as fd:
            contents = fd.read()
            baseline = struct.unpack((int(len(contents) / 8)) * "d", contents)

        self.assertEqual(len(baseline), 2 * len(magnetization))
        for i in range(len(magnetization)):
            self.assertAlmostEqual(sycomore.transversal(magnetization[i]),
                                   baseline[2 * i])
            self.assertAlmostEqual(magnetization[i][2], baseline[2 * i + 1])
Esempio n. 4
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    def test_pulse(self):
        model = sycomore.como.Model(
            sycomore.Species(1 * s, 0.1 * s), sycomore.Magnetization(0, 0, 1),
            [["dummy", sycomore.TimeInterval(0 * s)]])

        model.apply_pulse(sycomore.Pulse(41 * deg, 27 * deg))

        grid = model.magnetization()
        for index, _ in sycomore.GridScanner(grid.origin(), grid.shape()):
            if index == sycomore.Index(0):
                self.assertAlmostEqual(grid[index].p,
                                       0.210607912662250 - 0.413341301933443j)
                self.assertAlmostEqual(grid[index].z, 0.754709580222772)
                self.assertAlmostEqual(grid[index].m,
                                       0.210607912662250 + 0.413341301933443j)
            else:
                self.assertEqual(grid[index].p, 0)
                self.assertAlmostEqual(grid[index].z, 0)
                self.assertAlmostEqual(grid[index].m, 0)
Esempio n. 5
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    def test_time_interval(self):
        model = sycomore.como.Model(
            sycomore.Species(math.log(2) * Hz,
                             math.log(2) * Hz),
            sycomore.Magnetization(0, 0, 1),
            [["foo", sycomore.TimeInterval(1 * s)],
             ["bar", sycomore.TimeInterval(1 * s)]])

        model.apply_pulse(sycomore.Pulse(45 * deg, 90 * deg))

        model.apply_time_interval("foo")

        grid = model.magnetization()
        for index, _ in sycomore.GridScanner(grid.origin(), grid.shape()):
            if index == sycomore.Index(-1, 0):
                self.assertEqual(grid[index].p, 0)
                self.assertEqual(grid[index].z, 0)
                self.assertAlmostEqual(grid[index].m, 0.25)
            elif index == sycomore.Index(0, 0):
                self.assertEqual(grid[index].p, 0)
                self.assertEqual(grid[index].z, 0.5 * (1 + math.sqrt(2) / 2))
                self.assertEqual(grid[index].m, 0)
            elif index == sycomore.Index(1, 0):
                self.assertAlmostEqual(grid[index].p, 0.25)
                self.assertEqual(grid[index].z, 0)
                self.assertEqual(grid[index].m, 0)
            else:
                self.assertEqual(grid[index].p, 0)
                self.assertAlmostEqual(grid[index].z, 0)
                self.assertAlmostEqual(grid[index].m, 0)

        model.apply_time_interval("bar")

        grid = model.magnetization()
        for index, _ in sycomore.GridScanner(grid.origin(), grid.shape()):
            if index == sycomore.Index(-1, -1):
                self.assertEqual(grid[index].p, 0)
                self.assertEqual(grid[index].z, 0)
                self.assertAlmostEqual(grid[index].m, 0.125)
            elif index == sycomore.Index(0, 0):
                self.assertEqual(grid[index].p, 0)
                self.assertEqual(grid[index].z,
                                 0.5 + 0.25 * (1 + math.sqrt(2) / 2))
                self.assertEqual(grid[index].m, 0)
            elif index == sycomore.Index(1, 1):
                self.assertAlmostEqual(grid[index].p, 0.125)
                self.assertEqual(grid[index].z, 0)
                self.assertEqual(grid[index].m, 0)
            else:
                self.assertEqual(grid[index].p, 0)
                self.assertAlmostEqual(grid[index].z, 0)
                self.assertAlmostEqual(grid[index].m, 0)

        isochromat = model.isochromat()
        self.assertAlmostEqual(isochromat[0], 0.125 * math.sqrt(2))
        self.assertAlmostEqual(isochromat[1], 0)
        self.assertAlmostEqual(isochromat[2],
                               0.5 + 0.25 * (1 + math.sqrt(2) / 2))

        isochromat = model.isochromat(
            {sycomore.Index(0, 0),
             sycomore.Index(-1, -1)})
        self.assertAlmostEqual(isochromat[0], 0.125 * math.sqrt(2) / 2)
        self.assertAlmostEqual(isochromat[1], 0)
        self.assertAlmostEqual(isochromat[2],
                               0.5 + 0.25 * (1 + math.sqrt(2) / 2))
Esempio n. 6
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    def test_pulse_profile(self):
        species = sycomore.Species(0*Hz, 0*Hz, 0*um*um/ms)
        m0 = sycomore.Magnetization(0, 0, 1)

        pulse = sycomore.Pulse(90*deg, math.pi*rad)
        pulse_duration = 1*ms
        pulse_support_size = 101
        zero_crossings = 2

        # NOTE: in the absence of relaxation and diffusion, the TR is meaningless
        TR = 500*ms;
        slice_thickness = 1*mm;

        sampling_support_size = 501

        t0 = pulse_duration/(2*zero_crossings)
        sinc_pulse = sycomore.HardPulseApproximation(
            pulse,
            sycomore.linspace(pulse_duration, pulse_support_size),
            sycomore.sinc_envelope(t0), 1/t0, slice_thickness, "rf")

        refocalization = sycomore.TimeInterval(
            (TR-pulse_duration)/2., -sinc_pulse.get_gradient_moment()/2)

        sampling_locations = sycomore.linspace(
            sycomore.Point(0*m, 0*m, 2*slice_thickness), sampling_support_size)

        model = sycomore.como.Model(
            species, m0, [
                ["rf", sinc_pulse.get_time_interval()],
                ["refocalization", refocalization]])

        model.apply_pulse(sinc_pulse)

        before_refocalization = [
            model.isochromat(set(), p) for p in sampling_locations]

        model.apply_time_interval("refocalization")

        after_refocalization = [
            model.isochromat(set(), p) for p in sampling_locations]

        root = os.environ["SYCOMORE_TEST_DATA"]
        with open(os.path.join(root, "baseline", "pulse_profile.dat"), "rb") as fd:
            contents = fd.read()
            baseline = struct.unpack((int(len(contents)/8))*"d", contents)

        self.assertEqual(len(baseline), 2*3*len(sampling_locations))
        for i in range(len(sampling_locations)):
            m_test = before_refocalization[i]
            m_baseline = baseline[3*i:3*(i+1)]

            self.assertAlmostEqual(m_test[0], m_baseline[0])
            self.assertAlmostEqual(m_test[1], m_baseline[1])
            self.assertAlmostEqual(m_test[2], m_baseline[2])
        for i in range(len(sampling_locations)):
            m_test = after_refocalization[i]
            m_baseline = baseline[
                3*(i+len(sampling_locations)):3*(i+len(sampling_locations)+1)]

            self.assertAlmostEqual(m_test[0], m_baseline[0])
            self.assertAlmostEqual(m_test[1], m_baseline[1])
            self.assertAlmostEqual(m_test[2], m_baseline[2])