wide-line spectra handle missing x values better #303
@ -542,7 +542,9 @@ class UpperManagement(QtCore.QObject):
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elif fit_limits[0] == 'in':
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elif fit_limits[0] == 'in':
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inside = np.where((_x >= fit_limits[1][0]) & (_x <= fit_limits[1][1]))
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inside = np.where((_x >= fit_limits[1][0]) & (_x <= fit_limits[1][1]))
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else:
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else:
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inside = np.where((_x < fit_limits[1][0]) | (_x > fit_limits[1][1]))
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x_lim, _ = self.graphs[self.current_graph].ranges
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inside_graph = (_x >= x_lim[0]) & (_x <= x_lim[1])
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inside = np.where(((_x < fit_limits[1][0]) | (_x > fit_limits[1][1])) & inside_graph)
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try:
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try:
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if isinstance(we, str):
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if isinstance(we, str):
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@ -3,11 +3,42 @@ try:
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from scipy.integrate import simpson
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from scipy.integrate import simpson
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except ImportError:
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except ImportError:
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from scipy.integrate import simps as simpson
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from scipy.integrate import simps as simpson
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from numpy import pi
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from ..math.orientations import zcw_spherical as crystallites
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from ..math.orientations import zcw_spherical as crystallites
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__all__ = ['CSA', 'Pake', 'SecCentralLine']
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def _make_broadening(x: np.ndarray, sigma: float, mode: str):
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dx = x[1] - x[0]
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_x = np.arange(len(x)) * dx
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_x -= 0.5 * _x[-1]
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if mode == 'l':
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apd = 2 * sigma / (4*_x**2 + sigma**2) / np.pi
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else:
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ln2 = np.log(2)
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apd = np.exp(-4*ln2 * (_x/sigma)**2) * 2 * np.sqrt(ln2/np.pi) / sigma
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return apd
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def _make_bins(x: np.ndarray) -> np.ndarray:
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bins = 0.5 * (x[1:] + x[:-1])
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return np.r_[0.5 * (-x[1] + 3 * x[0]), bins, 0.5 * (3 * x[-1] - x[-2])]
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def _make_x(x: np.ndarray) -> tuple[np.ndarray, np.ndarray]:
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_x = x
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dx = x[1:] - x[:-1]
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dx = np.min(dx)
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width = x[-1] - x[0]
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_x = np.arange(width/dx - 1) * dx + x[0]
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bins = (_x[1:] + _x[:-1]) / 2
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bins = np.r_[_x[0]-dx/2, bins, _x[-1] + dx/2]
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return _x, bins
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class Pake:
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class Pake:
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type = 'Spectrum'
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type = 'Spectrum'
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name = 'Pake'
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name = 'Pake'
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@ -17,38 +48,39 @@ class Pake:
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choices = [('Broadening', 'broad', {'Gaussian': 'g', 'Lorentzian': 'l'})]
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choices = [('Broadening', 'broad', {'Gaussian': 'g', 'Lorentzian': 'l'})]
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@staticmethod
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@staticmethod
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def func(x, c, delta, eta, sigma, t_pulse, broad='g'):
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def func(
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x: np.ndarray,
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c: float,
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delta: float,
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eta: float,
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sigma: float,
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t_pulse: float,
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broad: str = 'g',
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) -> np.ndarray:
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a, b, _ = crystallites(100000)
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a, b, _ = crystallites(100000)
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bins = 0.5 * (x[1:] + x[:-1])
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bins = np.r_[0.5*(3*x[0]-x[1]), bins, 0.5*(3*x[-1]-x[-2])]
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omega = delta * 0.5 * (3*np.cos(b)**2 - 1 - eta * np.sin(b)**2 * np.cos(2*a))
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omega = delta * 0.5 * (3*np.cos(b)**2 - 1 - eta * np.sin(b)**2 * np.cos(2*a))
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x_used, bins = _make_x(x)
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s_left = np.histogram(omega, bins=bins)[0]
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s_left = np.histogram(omega, bins=bins)[0]
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s_right = np.histogram(-omega, bins=bins)[0]
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s_right = np.histogram(-omega, bins=bins)[0]
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s = s_left + s_right
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s = s_left + s_right
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if sigma != 0:
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if sigma != 0:
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_x = np.arange(len(x))*(x[1]-x[0])
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apd = _make_broadening(x_used, sigma, broad)
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_x -= 0.5*_x[-1]
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if broad == 'l':
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apd = 2 * sigma / (4 * _x**2 + sigma**2) / pi
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else:
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apd = np.exp(-4 * np.log(2) * (_x/sigma)**2) * 2 * np.sqrt(np.log(2) / pi) / sigma
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ret_val = np.convolve(s, apd, mode='same')
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ret_val = np.convolve(s, apd, mode='same')
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else:
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else:
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ret_val = s
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ret_val = s
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omega_1 = pi/2/t_pulse
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omega_1 = np.pi/2/t_pulse
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attn = omega_1 * np.sin(t_pulse*np.sqrt(omega_1**2+0.5*(2*pi*x)**2)) / \
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attn = omega_1 * np.sin(t_pulse*np.sqrt(omega_1**2 + 0.5*(2*np.pi*x_used)**2)) / np.sqrt(omega_1**2 + (np.pi*x_used)**2)
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np.sqrt(omega_1**2+(np.pi*x)**2)
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ret_val *= attn
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ret_val *= attn
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ret_val /= simpson(y=ret_val, x=x_used)
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return c * ret_val / simpson(ret_val, x)
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if x_used.size == x.size:
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return c * ret_val
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else:
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return c * np.interp(x=x, xp=x_used, fp=ret_val)
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class CSA:
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class CSA:
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@ -60,28 +92,29 @@ class CSA:
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choices = [('Broadening', 'broad', {'Gaussian': 'g', 'Lorentzian': 'l'})]
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choices = [('Broadening', 'broad', {'Gaussian': 'g', 'Lorentzian': 'l'})]
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@staticmethod
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@staticmethod
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def func(x, c, delta, eta, w_iso, sigma, broad='g'):
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def func(
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x: np.ndarray,
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c: float,
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delta: float,
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eta: float,
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w_iso: float,
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sigma: float,
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broad: str = 'g',
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) -> np.ndarray:
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a, b, _ = crystallites(100000)
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a, b, _ = crystallites(100000)
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bins = 0.5 * (x[1:] + x[:-1])
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bins = np.r_[0.5*(-x[1] + 3*x[0]), bins, 0.5*(3*x[-1] - x[-2])]
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omega = w_iso + delta * 0.5 * (3*np.cos(b)**2 - 1 - eta * np.sin(b)**2 * np.cos(2*a))
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omega = w_iso + delta * 0.5 * (3*np.cos(b)**2 - 1 - eta * np.sin(b)**2 * np.cos(2*a))
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s_left = np.histogram(omega, bins=bins)[0]
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s = np.histogram(omega, bins=_make_bins(x))[0]
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s = s_left
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if sigma != 0:
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if sigma != 0:
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_x = np.arange(len(x)) * (x[1] - x[0])
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print(len(s))
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_x -= 0.5 * _x[-1]
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apd = _make_broadening(x, sigma, broad)
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if broad == 'l':
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apd = 2 * sigma / (4*_x**2 + sigma**2) / pi
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else:
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apd = np.exp(-4 * np.log(2) * (_x / sigma) ** 2) * 2 * np.sqrt(np.log(2) / pi) / sigma
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ret_val = np.convolve(s, apd, mode='same')
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ret_val = np.convolve(s, apd, mode='same')
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else:
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else:
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ret_val = s
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ret_val = s
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return c * ret_val / simpson(ret_val, x)
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return c * ret_val / simpson(y=ret_val, x=x)
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class SecCentralLine:
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class SecCentralLine:
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@ -94,10 +127,18 @@ class SecCentralLine:
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('Broadening', 'broad', {'Gaussian': 'g', 'Lorentzian': 'l'})]
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('Broadening', 'broad', {'Gaussian': 'g', 'Lorentzian': 'l'})]
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@staticmethod
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@staticmethod
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def func(x, c, cq, eta, f_iso, gb, f_l, spin=2.5, broad='g'):
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def func(
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x: np.ndarray,
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c: float,
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cq: float,
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eta: float,
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f_iso: float,
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gb: float,
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f_l: float,
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spin: float = 2.5,
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broad: str = 'g',
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) -> np.ndarray:
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a, b, _ = crystallites(200000)
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a, b, _ = crystallites(200000)
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bins = 0.5 * (x[1:] + x[:-1])
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bins = np.r_[0.5*(-x[1] + 3*x[0]), bins, 0.5*(3*x[-1] - x[-2])]
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# coupling constant
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# coupling constant
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omega_q = 2 * np.pi * cq / (2*spin*(2*spin-1))
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omega_q = 2 * np.pi * cq / (2*spin*(2*spin-1))
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@ -116,17 +157,12 @@ class SecCentralLine:
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orient += prefactor_c
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orient += prefactor_c
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omega = 2*np.pi*f_iso + coupling * orient
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omega = 2*np.pi*f_iso + coupling * orient
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s = np.histogram(omega / (2*np.pi), bins=bins)[0]
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s = np.histogram(omega / (2*np.pi), bins=_make_bins(x))[0]
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if gb != 0:
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if gb != 0:
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_x = np.arange(len(x)) * (x[1]-x[0])
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apd = _make_broadening(x, gb, broad)
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_x -= 0.5*_x[-1]
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if broad == 'l':
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apd = 2*gb / (4*_x**2 + gb**2) / np.pi
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else:
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apd = np.exp(-4*np.log(2) * (_x/gb)**2) * 2 * np.sqrt(np.log(2)/np.pi) / gb
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ret_val = np.convolve(s, apd, mode='same')
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ret_val = np.convolve(s, apd, mode='same')
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else:
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else:
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ret_val = s
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ret_val = s
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return c * ret_val / simpson(ret_val, x)
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return c * ret_val / simpson(y=ret_val, x=x)
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Loading…
Reference in New Issue
Block a user