def update_units_labels_and_values(self) -> None:
""" Updates the x units labels and fields
:return: None
"""
# If x units haven't changed, we do nothing
new_x = self.units.get().split('_')[-1]
old_x = self.units_x.get()
if new_x == old_x:
return
self.units_x.set(new_x)
old_min = self.x_min.get()
old_max = self.x_max.get()
if all(t in ('nm', 'eV') for t in (old_x, new_x)):
new_min = eVnm(old_min)
new_max = eVnm(old_max)
elif all(t in ('nm', 'J') for t in (old_x, new_x)):
new_min = nmJ(old_min)
new_max = nmJ(old_max)
elif all(t in ('nm', 'm') for t in (old_x, new_x)):
factor = 1e-9 if old_x == 'nm' else 1e9
new_min = factor * old_min
new_max = factor * old_max
elif all(t in ('nm', 'hz') for t in (old_x, new_x)):
new_min = nmHz(old_min)
new_max = nmHz(old_max)
elif all(t in ('m', 'J') for t in (old_x, new_x)):
new_min = mJ(old_min)
new_max = mJ(old_max)
elif all(t in ('m', 'eV') for t in (old_x, new_x)):
factor = h * c / q
new_min = factor / old_min
new_max = factor / old_max
elif all(t in ('m', 'hz') for t in (old_x, new_x)):
factor = c
new_min = factor / old_min
new_max = factor / old_max
elif all(t in ('J', 'eV') for t in (old_x, new_x)):
factor = q if old_x == 'eV' else 1 / q
new_min = factor * old_min
new_max = factor * old_max
elif all(t in ('J', 'hz') for t in (old_x, new_x)):
factor = 1 / h if old_x == 'J' else h
new_min = factor * old_min
new_max = factor * old_max
else:
# eV <-> hz
factor = q / h if old_x == 'eV' else h / q
new_min = factor * old_min
new_max = factor * old_max
# Now we have to check if maximum and minimum are in the correct order, reversing them, otherwise
if new_min > new_max:
new_min, new_max = new_max, new_min
self.x_min.set(format(new_min, '.4'))
self.x_max.set(format(new_max, '.4'))
def _get_photon_flux_per_J(self, energy):
""" Function that returns the spectrum in photon flux per Joule.
:param energy: Array with the energies at which to calculate the spectrum (in J)
:return: The spectrum in the chosen units.
"""
wavelength = nmJ(energy)[::-1]
output = self._spectrum(wavelength)
energy_eV, output = spectral_conversion_nm_ev(wavelength, output)
output = output / (q * energy)
return output
def photon_flux_per_joule(spectrum: Callable[[np.ndarray], np.ndarray], x: np.ndarray):
""" Function that returns the spectrum in photon flux per Joule.
The input spectrum is assumed to be in power density per nanometer.
:param spectrum: The spectrum to interpolate.
:param x: Array with the energies (in J)
:return: The spectrum in the chosen units.
"""
wavelength = nmJ(x)[::-1]
output = spectrum(wavelength)
_, output = spectral_conversion_nm_ev(wavelength, output)
return output / (q * x)
