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Optimal Management of Grid-Interactive Efficient Buildings via Safe Reinforcement Learning

Xiang Huo, Boming Liu, Jin Dong, Jianming Lian, Mingxi Liu

TL;DR

Simulations on the optimal management of GEBs, including heating, ventilation, and air conditioning (HVAC), solar photovoltaics, and energy storage systems, demonstrate the effectiveness of the proposed safe RL method.

Abstract

Reinforcement learning (RL)-based methods have achieved significant success in managing grid-interactive efficient buildings (GEBs). However, RL does not carry intrinsic guarantees of constraint satisfaction, which may lead to severe safety consequences. Besides, in GEB control applications, most existing safe RL approaches rely only on the regularisation parameters in neural networks or penalty of rewards, which often encounter challenges with parameter tuning and lead to catastrophic constraint violations. To provide enforced safety guarantees in controlling GEBs, this paper designs a physics-inspired safe RL method whose decision-making is enhanced through safe interaction with the environment. Different energy resources in GEBs are optimally managed to minimize energy costs and maximize customer comfort. The proposed approach can achieve strict constraint guarantees based on prior knowledge of a set of developed hard steady-state rules. Simulations on the optimal management of GEBs, including heating, ventilation, and air conditioning (HVAC), solar photovoltaics, and energy storage systems, demonstrate the effectiveness of the proposed approach.

Optimal Management of Grid-Interactive Efficient Buildings via Safe Reinforcement Learning

TL;DR

Simulations on the optimal management of GEBs, including heating, ventilation, and air conditioning (HVAC), solar photovoltaics, and energy storage systems, demonstrate the effectiveness of the proposed safe RL method.

Abstract

Reinforcement learning (RL)-based methods have achieved significant success in managing grid-interactive efficient buildings (GEBs). However, RL does not carry intrinsic guarantees of constraint satisfaction, which may lead to severe safety consequences. Besides, in GEB control applications, most existing safe RL approaches rely only on the regularisation parameters in neural networks or penalty of rewards, which often encounter challenges with parameter tuning and lead to catastrophic constraint violations. To provide enforced safety guarantees in controlling GEBs, this paper designs a physics-inspired safe RL method whose decision-making is enhanced through safe interaction with the environment. Different energy resources in GEBs are optimally managed to minimize energy costs and maximize customer comfort. The proposed approach can achieve strict constraint guarantees based on prior knowledge of a set of developed hard steady-state rules. Simulations on the optimal management of GEBs, including heating, ventilation, and air conditioning (HVAC), solar photovoltaics, and energy storage systems, demonstrate the effectiveness of the proposed approach.
Paper Structure (14 sections, 24 equations, 7 figures, 1 algorithm)

This paper contains 14 sections, 24 equations, 7 figures, 1 algorithm.

Table of Contents

  1. Introduction
  2. System Model and Algorithm Design
  3. System Model
  4. Dynamic building thermal network model
  5. Solar photovoltaic
  6. Energy storage system
  7. Objectives
  8. Algorithm Design
  9. Markov decision process
  10. Steady-state analysis
  11. Safe layer design
  12. Deep Q-networks
  13. Simulations
  14. Conclusion

Figures (7)

  • Figure 1: Physics-inspired safe RL structure.
  • Figure 2: The structure of the proposed safe-RL network based on DQN.
  • Figure 3: Indoor room temperature and HVAC power supply.
  • Figure 4: Original actions and regulated safe actions during the HVAC control.
  • Figure 5: Solar power injection from the solar PVs.
  • ...and 2 more figures