Abstract

With the increasing penetration of renewable resources such as wind and solar, especially in terms of large-scale integration, the operation and planning of power systems are faced with great risks due to the inherent stochasticity of natural resources. Although this uncertainty can be anticipated, the timing, magnitude, and duration of fluctuations cannot be predicted accurately. In addition, the outputs of renewable power sources are correlated in space and time, and this brings further challenges for predicting the characteristics of their future behavior. To address these issues, this paper describes an unsupervised distribution learning method for renewable scenario forecasts that considers spatiotemporal correlation based on generative adversarial network (GAN), which has been shown to generate realistic time series for stochastic processes. We first utilize an improved GAN to learn unknown data distributions and model the dynamic processes of renewable resources. We then generate a large number of forecasted scenarios using stochastic constrained optimization. For validation, we use power generation data from the National Renewable Energy Laboratory wind and solar integration datasets. The simulation results show that the generated trajectories not only reflect the future power generation dynamics, but also correctly capture the temporal, spatial, and fluctuant characteristics of the real power generation processes. The experimental comparisons verify the superiority of the proposed method and indicate that it can reduce at least 50% of the training iterations of the generative model for scenario forecasts.

Highlights

  • 9 To tackle this issue, we propose a data-driven method based on generative adversarial network to forecast renewable scenarios 10 for multiple geographical locations

  • To further check whether the discriminator overfits and provides an inaccurate estimate of a training point at which all bets are correlated with sample quality, we explored the behavior of the loss curves from the test sets

  • 4 we focus on the scenario forecasting problem, this information can be provided by any method, e.g., information from numerical

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Summary

Summary

With the increasing penetration of renewable resources such as wind and solar, especially in terms of large-scale integration, the operation and planning of power systems are faced with great risks due to the inherent stochasticity of natural resources This uncertainty can be anticipated, the timing, magnitude, and duration of fluctuations cannot be predicted accurately. The outputs of renewable power sources are correlated in space and time, and this brings further challenges for predicting the characteristics of their future behavior To address these issues, this paper describes an unsupervised distribution learning method for renewable scenario forecasts that considers spatiotemporal correlation based on generative adversarial network (GAN), which has been shown to generate realistic time series for stochastic processes.

Parameters N K
12 CONCLUSION AND FUTURE WORK
Findings
30 References

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