Release of solar panel dataset helps cities make power grids more safe, reliable

Release of solar panel dataset helps cities make power grids more safe, reliable
Map of Australia highlighting Perth, Western Australia; Adelaide, South Australia; and Canberra, Australian Capital Territory. Each red marker represents the location of the PV systems within the database. Longitude and latitude are reported in degrees. Credit: Australian National University

Solar power researchers have traditionally only used the power measurements from single residential solar photovoltaic (PV) systems to estimate the power generated within a city. But one installation isn't a good representation of all the rooftops in the city, where the time of day, panel direction, and shade cast by trees and clouds affect power production.

Data from PV systems distributed across a city is desperately needed to fully understand how this can be integrated into the without disrupting the reliable flow of electricity on which the depends.

Engineers from the Australian National University and Fraunhofer-Institute for Solar Energy Systems ISE, Germany, have provided a freely available quality-controlled and tuned dataset from 1,287 residential installations across Australia. The dataset is presented in the Journal of Renewable and Sustainable Energy.

Describing the dataset as "a gift" for solar researchers, author Jamie Bright said, "No one has delivered a freely accessible piece of data that has six months' worth of measurements from three different cities. That is a significant amount."

Bright explained that previously, researchers had been pushed to extremes to gather power measurements, inventing cloud models moving across a city to "fake" PV power output for different locations.

"For the first time, you are able to easily access data and do the sort of spatial analysis needed to manage solar integration into the grid in a controlled way," said Bright.

In Australia, where approximately 23% of all residential homes have PV systems, this is particularly relevant for the safe and reliable management of the grid. For instance, to maintain the recommended voltage for appliances and to ensure , grid operators need to react and plan for solar power fluctuations.

By subscribing to a public website——Bright and colleagues were able to access raw PV data supplied by the automatic logging of PV system's electrical converters. A extracted data from the website and put it into a database for the engineers, who then collected characteristic details about each PV system, such as its size and efficiency. Using this metadata alongside , they performed rigorous quality controls and trained tuning algorithms on the dataset to clear up any "bad data."

"Our tuning routine is a catchall method of finding all the possible systemlike losses, such as shading, and removing them from the data. Not just deleting them, but scaling it back up to make it representative," said Bright.

The representative scenario can then be extrapolated to greater areas and used in tandem with satellites to improve solar forecasting.

"Now we've proved with this dataset that live reporting PV systems can significantly improve forecasting—solar forecasting companies are deploying our approach to a real operational industrial forecasting system," said Bright.

By providing the codes and instructions for their dataset at each processing stage, Bright hopes they are giving other researchers a head start.

More information: "Data article: Distributed PV power data for three cities in Australia," Journal of Renewable and Sustainable Energy (2019). DOI: 10.1063/1.5094059

Citation: Release of solar panel dataset helps cities make power grids more safe, reliable (2019, May 28) retrieved 15 July 2024 from
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.

Explore further

No more cloudy days for solar


Feedback to editors