A Computational Framework for Assessing Solar Photovoltaic Potential of Buildings Based on LiDAR and Building Footprint Data

Abstract

The mass adoption of building-integrated photovoltaics (BIPV) emerges as a promising solution for reducing global greenhouse gas (GHG) emissions. However, using such systems to achieve net zero operational energy at the urban scale requires evaluating the solar potential of thousands of buildings which poses many challenges concerning data availability, quality, and privacy. To address these issues, we present an automated end-to-end framework for querying, combining, and processing publicly available aerial Light Detection and Ranging (LiDAR) and Building Footprint data. Using open-source algorithms for geometry reconstruction and solar radiation analysis, we show how to estimate the maximum annual direct current (DC) electricity yield per building. This framework is designed to enable urban planners, developers, and architects to assess the solar potential of neighborhoods and cities in an accessible way. By enabling effective communication of results, it can help optimize resource allocation and benefit solar adoption initiatives.

Keywords

BIPV, Performance-based design, Photovoltaic potential, Spatial data processing, Renewable energy, Urban planning

Author

• Name: Silvia Vangelova
• LinkedIn: Link
• Institution: Georgia Institute of Technology
• Program: M.S. Analytics (OMSA)
• Advisor: Dr. Patrick Kastner

Repository Structure

• Code/: Directory containing the code, scripts, or notebooks used in the research.
  • Grasshopper/: Directory containing the grasshopper definition
    • data/: Directory containing data for the grasshoper script
  • Notebooks/: Directory containing notebooks
    • images/: Directory containing images produces from running the Notebooks
    • data/: Directory for storing data produced from running the Notebooks
• Resources/: Directory containing images used in this README.md file.
• README.md: This file, providing an overview of the thesis and repository.

Instructions for reconstructing mesh geometry in Jupyter Notebook

Environment set-up:

• python -m venv env
• env\Scripts\activate
• pip install -r requirements.txt

Running the Solar Potential Analysis script in Grsshopper instructions

The grasshopper definition is developed in Rhino 8 SR10 (8.10.24228.13001, 2024-08-15) on Windows. For this version, there are certain issues when importing pandas (see forum discussion here)

1. Before starting Grasshopper make, sure to open the ScriptEditor and run the following script to import numpy, pandas, and laspy:

   

   Code snippet:

   import locale
   import numpy
   locale.setlocale(locale.LC_ALL, 'en_US.UTF-8')
   import pandas as pd
   import laspy

2. To install python packages in Rhino 8 you can either install them from the Terminal or use the # r: %package name% notation

   Using Terminal

   1. Open command prompt
   2. Navigate to script environment, e.g. run: cd "C:\Users\%UserName%\.rhinocode\py39-rh8\Scripts"
   3. Instal packages, e.g. run pip install pandas

   Using the # r: %package name% notation:

   

   See also this tutorial for using packages in Rhino 8

3. To run the script make sure the following packages are installed and can be imported properly:

   rasterio
   laspy
   lazrs
   laszip
   geopy
   scikit-learn
   scipy
   cgal
   requests
   rasterio
   geopandas
   osmnx

Citation

@inproceedings{vangelova2024sigradi,
  title = {A Computational Framework for Assessing Solar Photovoltaic Potential of Buildings Based on LiDAR and Building Footprint Data},
  author = {Vangelova, Silvia},
  year = {2024},
  booktitle = {Proceedings of SIGRADI 2024},
  institution = {Georgia Institute of Technology},
  bibtex_show       = {true},
  preview           = {SIGRADI2024.png},
}

Source

Link to this repository.