Metadata-Version: 2.1
Name: laserbeamsize
Version: 2.0.0
Summary: ISO 11146 Calculation of Laser Beam Center, Diameter, and M²
Home-page: https://github.com/scottprahl/laserbeamsize.git
Author: Scott Prahl
Author-email: scott.prahl@oit.edu
License: MIT
Keywords: variance,gaussian,M-squared,d4sigma,M2,M²,spotsize,laser beam,IS011146,divergence,beam waist,TEM00,beam diameter,beam parameter product,BPP
Classifier: Development Status :: 5 - Production/Stable
Classifier: License :: OSI Approved :: MIT License
Classifier: Intended Audience :: Science/Research
Classifier: Programming Language :: Python
Classifier: Programming Language :: Python :: 3.8
Classifier: Programming Language :: Python :: 3.9
Classifier: Programming Language :: Python :: 3.10
Classifier: Programming Language :: Python :: 3.11
Classifier: Topic :: Scientific/Engineering :: Physics
Requires-Python: >=3.5
Description-Content-Type: text/x-rst
License-File: LICENSE.txt
Requires-Dist: numpy
Requires-Dist: matplotlib
Requires-Dist: scipy
Requires-Dist: imageio

laserbeamsize
=============

by Scott Prahl

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    **Do not use latest github code. It doesn't work. Use the last released version v1.9.4.**

__________

Simple and fast calculation of beam sizes from a single monochrome image based
on the ISO 11146 method of variances.  Some effort has been made to make the 
algorithm less sensitive to background offset and noise.

This module also supports M² calculations based on a series of images
collected at various distances from the focused beam. 

Extensive documentation can be found at <https://laserbeamsize.readthedocs.io>


Using laserbeamsize
-------------------

1. Install with ``pip``::
    
    pip install --user laserbeamsize

2. or `run this code in the cloud using Google Collaboratory <https://colab.research.google.com/github/scottprahl/laserbeamsize/blob/master>`_ by selecting the Jupyter notebook that interests you.

3. use `binder <https://mybinder.org/v2/gh/scottprahl/laserbeamsize/master?filepath=docs>`_ which will create a new environment that allows you to run Jupyter notebooks.  This takes a bit longer to start, but it automatically installs ``laserbeamsize``.

4. clone the `laserbeamsize github repository <https://github.com/scottprahl/laserbeamsize>`_ and then add the repository to your ``PYTHONPATH`` environment variable

Determining the beam size in an image
-------------------------------------

Finding the center and dimensions of a good beam image::

    import imageio
    import numpy as np
    import matplotlib.pyplot as plt
    import laserbeamsize as lbs

    beam = imageio.v2.imread("t-hene.pgm")
    x, y, dx, dy, phi = lbs.beam_size(beam)

    print("The center of the beam ellipse is at (%.0f, %.0f)" % (x,y))
    print("The ellipse diameter (closest to horizontal) is %.0f pixels" % dx)
    print("The ellipse diameter (closest to   vertical) is %.0f pixels" % dy)
    print("The ellipse is rotated %.0f° ccw from horizontal" % (phi*180/3.1416))

to produce::

    The center of the beam ellipse is at (651, 491)
    The ellipse diameter (closest to horizontal) is 334 pixels
    The ellipse diameter (closest to   vertical) is 327 pixels
    The ellipse is rotated 29° ccw from the horizontal

A visual report can be done with one function call::

    lbs.beam_size_plot(beam)
    plt.show()
    
produces something like

.. image:: https://raw.githubusercontent.com/scottprahl/laserbeamsize/master/docs/hene-report.png
   :alt: HeNe report

or::

    lbs.beam_size_plot(beam, r"Original Image $\lambda$=4µm beam", pixel_size = 12, units='µm')
    plt.show()

produces something like

.. image:: https://raw.githubusercontent.com/scottprahl/laserbeamsize/master/docs/astigmatic-report.png
   :alt: astigmatic report

Non-gaussian beams work too::

    # 12-bit pixel image stored as high-order bits in 16-bit values
    tem02 = imageio.imread("TEM02_100mm.pgm") >> 4
    lbs.beam_size_plot(tem02, title = r"TEM$_{02}$ at z=100mm", pixel_size=3.75)
    plt.show()

produces

.. image:: https://raw.githubusercontent.com/scottprahl/laserbeamsize/master/docs/tem02.png
   :alt: TEM02

Determining M² 
--------------

Determining M² for a laser beam is also straightforward.  Just collect beam diameters from
five beam locations within one Rayleigh distance of the focus and from five locations more
than two Rayleigh distances::

    lambda1=308e-9 # meters
    z1_all=np.array([-200,-180,-160,-140,-120,-100,-80,-60,-40,-20,0,20,40,60,80,99,120,140,160,180,200])*1e-3
    d1_all=2*np.array([416,384,366,311,279,245,216,176,151,120,101,93,102,120,147,177,217,256,291,316,348])*1e-6
    lbs.M2_radius_plot(z1_all, d1_all, lambda1, strict=True)
    plt.show()

produces

.. image:: https://raw.githubusercontent.com/scottprahl/laserbeamsize/master/docs/m2fit.png
   :alt: fit for M2

Here is an analysis of a set of images that do not meet the ISO 11146
requirements for determining M² (because the image locations are not taken
in right locations relative to the focus).  These beam images are from a HeNe
laser with slightly misaligned mirrors to primarily lase in a TEM₀₁ transverse mode.
The laser resonator had a fixed rotation of 38.7° from the plane of
the optical table.::

    lambda0 = 632.8e-9 # meters
    z10 = np.array([247,251,259,266,281,292])*1e-3 # meters
    filenames = ["sb_%.0fmm_10.pgm" % (number*1e3) for number in z10]

    # the 12-bit pixel images are stored in high-order bits in 16-bit values
    tem10 = [imageio.imread(name)>>4 for name in filenames]

    # remove top to eliminate artifact 
    for i in range(len(z10)):
        tem10[i] = tem10[i][200:,:]

    # find beam rotated by 38.7° in all images
    fixed_rotation = np.radians(38.7)
    options = {'pixel_size': 3.75, 'units': "µm", 'crop': [1400,1400], 'z':z10, 'phi':fixed_rotation}
    dy, dx= lbs.beam_size_montage(tem10, **options)  # dy and dx in microns
    plt.show()

produces

.. image:: https://raw.githubusercontent.com/scottprahl/laserbeamsize/master/docs/sbmontage.png
   :alt: montage of laser images

Here is one way to plot the fit using the above diameters::

    lbs.M2_diameter_plot(z10, dx*1e-6, lambda0, dy=dy*1e-6)
    plt.show()

In the graph on the below right, the dashed line shows the expected divergence
of a pure gaussian beam.  Since real beams should diverge faster than this (not slower)
there is some problem with the measurements (too few!).  On the other hand, the M² value 
the semi-major axis 2.6±0.7 is consistent with the expected value of 3 for the TEM₁₀ mode.

.. image:: https://raw.githubusercontent.com/scottprahl/laserbeamsize/master/docs/sbfit.png
   :alt: fit


License
-------

`laserbeamsize` is licensed under the terms of the MIT license.
