Benchmarking of Deep Learning Irradiance Forecasting Models from Sky
Images -- an in-depth Analysis
- URL: http://arxiv.org/abs/2102.00721v2
- Date: Tue, 2 Feb 2021 09:08:29 GMT
- Title: Benchmarking of Deep Learning Irradiance Forecasting Models from Sky
Images -- an in-depth Analysis
- Authors: Quentin Paletta, Guillaume Arbod and Joan Lasenby
- Abstract summary: We train four commonly used Deep Learning architectures to forecast solar irradiance from sequences of hemispherical sky images.
Results show that encodingtemporal aspects greatly improved the predictions with 10 min Forecast Skill reaching 20.4% on the test year.
We conclude that, with a common setup, Deep Learning models tend to behave just as a'very smart persistence model', temporally aligned with the persistence model while mitigating its most penalising errors.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: A number of industrial applications, such as smart grids, power plant
operation, hybrid system management or energy trading, could benefit from
improved short-term solar forecasting, addressing the intermittent energy
production from solar panels. However, current approaches to modelling the
cloud cover dynamics from sky images still lack precision regarding the spatial
configuration of clouds, their temporal dynamics and physical interactions with
solar radiation. Benefiting from a growing number of large datasets, data
driven methods are being developed to address these limitations with promising
results. In this study, we compare four commonly used Deep Learning
architectures trained to forecast solar irradiance from sequences of
hemispherical sky images and exogenous variables. To assess the relative
performance of each model, we used the Forecast Skill metric based on the smart
persistence model, as well as ramp and time distortion metrics. The results
show that encoding spatiotemporal aspects of the sequence of sky images greatly
improved the predictions with 10 min ahead Forecast Skill reaching 20.4% on the
test year. However, based on the experimental data, we conclude that, with a
common setup, Deep Learning models tend to behave just as a 'very smart
persistence model', temporally aligned with the persistence model while
mitigating its most penalising errors. Thus, despite being captured by the sky
cameras, models often miss fundamental events causing large irradiance changes
such as clouds obscuring the sun. We hope that our work will contribute to a
shift of this approach to irradiance forecasting, from reactive to
anticipatory.
Related papers
- Generalizing Weather Forecast to Fine-grained Temporal Scales via Physics-AI Hybrid Modeling [55.13352174687475]
This paper proposes a physics-AI hybrid model (i.e., WeatherGFT) which Generalizes weather forecasts to Finer-grained Temporal scales.
Specifically, we employ a carefully designed PDE kernel to simulate physical evolution on a small time scale.
We introduce a lead time-aware training framework to promote the generalization of the model at different lead times.
arXiv Detail & Related papers (2024-05-22T16:21:02Z) - Weather Prediction with Diffusion Guided by Realistic Forecast Processes [49.07556359513563]
We introduce a novel method that applies diffusion models (DM) for weather forecasting.
Our method can achieve both direct and iterative forecasting with the same modeling framework.
The flexibility and controllability of our model empowers a more trustworthy DL system for the general weather community.
arXiv Detail & Related papers (2024-02-06T21:28:42Z) - ExtremeCast: Boosting Extreme Value Prediction for Global Weather Forecast [57.6987191099507]
We introduce Exloss, a novel loss function that performs asymmetric optimization and highlights extreme values to obtain accurate extreme weather forecast.
We also introduce ExBooster, which captures the uncertainty in prediction outcomes by employing multiple random samples.
Our solution can achieve state-of-the-art performance in extreme weather prediction, while maintaining the overall forecast accuracy comparable to the top medium-range forecast models.
arXiv Detail & Related papers (2024-02-02T10:34:13Z) - Efficient Subseasonal Weather Forecast using Teleconnection-informed
Transformers [29.33938664834226]
Subseasonal forecasting is pivotal for agriculture, water resource management, and early warning of disasters.
Recent advances in machine learning have revolutionized weather forecasting by achieving competitive predictive skills to numerical models.
However, training such foundation models requires thousands of GPU days, which causes substantial carbon emissions.
arXiv Detail & Related papers (2024-01-31T14:27:35Z) - Learning Robust Precipitation Forecaster by Temporal Frame Interpolation [65.5045412005064]
We develop a robust precipitation forecasting model that demonstrates resilience against spatial-temporal discrepancies.
Our approach has led to significant improvements in forecasting precision, culminating in our model securing textit1st place in the transfer learning leaderboard of the textitWeather4cast'23 competition.
arXiv Detail & Related papers (2023-11-30T08:22:08Z) - Improving day-ahead Solar Irradiance Time Series Forecasting by
Leveraging Spatio-Temporal Context [46.72071291175356]
Solar power harbors immense potential in mitigating climate change by substantially reducing CO$_2$ emissions.
However, the inherent variability of solar irradiance poses a significant challenge for seamlessly integrating solar power into the electrical grid.
In this paper, we put forth a deep learning architecture designed to harnesstemporal context using satellite data.
arXiv Detail & Related papers (2023-06-01T19:54:39Z) - A Comparative Study on Generative Models for High Resolution Solar
Observation Imaging [59.372588316558826]
This work investigates capabilities of current state-of-the-art generative models to accurately capture the data distribution behind observed solar activity states.
Using distributed training on supercomputers, we are able to train generative models for up to 1024x1024 resolution that produce high quality samples indistinguishable to human experts.
arXiv Detail & Related papers (2023-04-14T14:40:32Z) - ECLIPSE : Envisioning Cloud Induced Perturbations in Solar Energy [2.867517731896504]
ECLIPSE is a neural network architecture that models cloud motion from sky images to predict both future segmented images and corresponding irradiance levels.
We show that ECLIPSE anticipates critical events and considerably reduces temporal delay while generating visually realistic futures.
arXiv Detail & Related papers (2021-04-26T09:19:43Z) - Smart Weather Forecasting Using Machine Learning:A Case Study in
Tennessee [2.9477900773805032]
We present a weather prediction technique that utilizes historical data from multiple weather stations to train simple machine learning models.
The accuracy of the models is good enough to be used alongside the current state-of-the-art techniques.
arXiv Detail & Related papers (2020-08-25T02:41:32Z) - Convolutional Neural Networks applied to sky images for short-term solar
irradiance forecasting [0.0]
This work presents preliminary results on the application of deep Convolutional Neural Networks for 2 to 20 min irradiance forecasting.
We evaluate the models on a set of irradiance measurements and corresponding sky images collected in Palaiseau (France) over 8 months with a temporal resolution of 2 min.
arXiv Detail & Related papers (2020-05-22T15:57:39Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.