Awesome
∂PV
A photovoltaic simulator with automatic differentation, built on JAX
.
Pull requests welcome!
Currently targeting inorganic materials.
For more examples, including performing efficiency optimization of a perovskite solar cell and discovering unknown material properties in a cell, see the following Google Colab
To install via pip
, simply use the command
pip install deltapv
deltapv
features a simple interface for most common cell structures. For a simple p-n homojunction, the following code computes the IV curve:
import deltapv as dpv
material = dpv.create_material(Chi=3.9,
Eg=1.5,
eps=9.4,
Nc=8e17,
Nv=1.8e19,
mn=100,
mp=100,
tn=1e-8,
tp=1e-8,
A=2e4)
des = dpv.make_design(n_points=500,
Ls=[1e-4, 1e-4],
mats=material,
Ns=[1e17, -1e17],
Snl=1e7,
Snr=0,
Spl=0,
Spr=1e7)
results = dpv.simulate(des)
Several convenient plotting functions are provided to visualize important quantities.
dpv.plot_iv_curve(*results["iv"])
dpv.plot_bars(des)
dpv.plot_band_diagram(des, results["eq"], eq=True)
dpv.plot_charge(des, results["eq"])
<img src="plots/iv.png" alt="iv" width="500"/>
<img src="plots/bars.png" alt="bars" width="500"/>
<img src="plots/band.png" alt="band" width="500"/>
<img src="plots/charge.png" alt="charge" width="500"/>
For an overview on PV cells and the physics behind the drift-diffusion model, see this helpful resource: https://www.pveducation.org.
If you use ∂PV, please kindly cite the following paper:
Mann, Sean, Eric Fadel, Samuel S. Schoenholz, Ekin D. Cubuk, Steven G. Johnson, and Giuseppe Romano.
"∂ PV: An end-to-end differentiable solar-cell simulator." Computer Physics Communications (2021): 108232 [pdf].