ref_index 1.0

Examples

Refractive index can be calculated using two different equations: one due to Edlén and another due to Ciddor.

>>> ref_index.ciddor(wave=633.0, t=20, p=101325, rh=20)
1.0002716285340578
>>> ref_index.edlen(wave=633.0, t=20, p=101325, rh=20)
1.0002716291691649
>>> ref_index.edlen(wave=633.0, t=20, p=101325, rh=80)
1.0002711197635226
>>> ref_index.ciddor(wave=633.0, t=20, p=101325, rh=80)
1.0002711183472626
>>> ref_index.edlen(wave=633.0, t=60, p=101325, rh=80)
1.0002339748542823
>>> ref_index.ciddor(wave=633.0, t=60, p=101325, rh=80)
1.0002340241754055

Conversion of wave length of light in vacuum to that in air, and vice-versa. Both of these functions use the Ciddor equation, as implemented in ciddor_ri() and ciddor().

>>> ref_index.vac2air(633.0)
632.82500476826874
>>> ref_index.air2vac(632.82500476826874)
633.00000139949032

>>> ref_index.vac2air(np.array([633.0, 550.0, 400.0]))
array([ 632.82500477,  549.84723175,  399.88692724])
>>> x = ref_index.vac2air(np.array([633.0, 550.0, 400.0]))
>>> ref_index.air2vac(x)
array([ 633.0000014 ,  550.00000164,  400.00000243])

Note that the reversibility of air2vac() is ~1e-5nm.

Default temperature is 15∘C, pressure is 101325Pa, relative humidity is 0, and CO2 concentration is 450µmole/mole. All these can be changed.

>>> ref_index.vac2air(633.0, t=20, p=100000.0, rh=50)
632.83051710791892
>>> ref_index.air2vac(632.83051710791892, t=20, p=100000.0, rh=50)
633.00000131884678

For more details please see the docstring for the module. Detailed description of the equations can be found in the NIST documentation.

Installation

The module can be installed using pip and easy_install.

$ pip install ref_index

or,

$ easy_install ref_index

Credits

All equations used in this module come from the documentation for the NIST online refractive index calculator, written by Jack A. Stone and Jay H. Zimmerman.

Please send comments and suggestions to the email id prasanthhn in the gmail.com domain.