REVIEW 2 major objections 2 minor 26 references
Reviewed by Pith at T0; open to challenge.
T0 means a machine referee read the full paper against a public rubric. The mark states how deep the mechanical check went, never who wrote it. the ladder, T0–T4 →
T0 review · grok-4.3
A supervised pre-training step on demonstrations followed by offline and online RL fine-tuning produces DER coordination policies that outperform benchmarks even with low-quality data.
2026-06-26 01:03 UTC pith:GTG3ZOD5
load-bearing objection The SRL framework pre-trains on demos then does offline-plus-online RL fine-tuning for DER coordination, but the abstract gives no evidence the two-step process survives distribution shift. the 2 major comments →
Supervised Reinforcement Learning for the Coordination of Distributed Energy Resources
The pith
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
The Supervised Reinforcement Learning framework pre-trains a policy on demonstration data in supervised fashion, then applies offline fine-tuning to boost performance and online fine-tuning to adapt to real-world dynamics; RL implementations of this framework significantly outperform all benchmarks and maintain high cost efficiency even when the demonstration data is low-quality.
What carries the argument
The two-step fine-tuning process (offline performance enhancement followed by online real-world adaptation) inside the Supervised Reinforcement Learning framework.
Load-bearing premise
The method assumes demonstration data exists that supplies a useful starting policy the RL steps can reliably improve without instability or excessive additional samples.
What would settle it
An experiment in which the online fine-tuning step produces policies with lower cost efficiency than the benchmarks or exhibits instability when deployed on actual DER systems would falsify the central claim.
If this is right
- Policies achieve high cost efficiency in coordinating DERs despite uncertainties and modelling complexity.
- The framework reduces the sample inefficiency that limits standard RL trained from scratch.
- Performance stays strong even when the initial demonstration data is low-quality.
- The approach combines the strengths of supervised learning and RL without requiring perfect expert data.
Where Pith is reading between the lines
- The same pre-train-then-fine-tune pattern could shorten the interaction budget needed for RL controllers in other infrastructure domains that already possess partial historical logs.
- Offline fine-tuning before live deployment might lower the risk of unsafe actions during early learning in safety-critical settings.
- Scaling the framework to larger numbers of DERs would test whether the adaptation step remains stable when the state space grows.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript proposes a Supervised Reinforcement Learning (SRL) framework for DER coordination that first pre-trains a policy via supervised learning on demonstration data, then applies a two-step RL fine-tuning process (offline RL followed by online RL) to adapt to real-world dynamics. Experiments are reported to show that SRL-based RL implementations significantly outperform all benchmarks in cost efficiency, including under low-quality demonstration data.
Significance. If the two-step fine-tuning process is shown to be robust, the framework could improve sample efficiency for RL in uncertain, high-dimensional energy systems and support practical DER management for decarbonization. The supervised pre-training step, modeled on LLM paradigms, offers a concrete way to bootstrap from available (even imperfect) data.
major comments (2)
- [Abstract, §Experiments] Abstract and §Experiments: the headline claim that SRL implementations 'significantly outperform all benchmarks' is stated without any reported baselines, metrics (e.g., cost, regret, or constraint violation), statistical tests, or error bars; the reader cannot verify whether results support superiority or reflect post-hoc selection.
- [Fine-tuning process description] § on two-step fine-tuning: the central assumption that offline-then-online fine-tuning reliably adapts the policy to real-world dynamics without instability or excessive sample cost is not supported by any reported analysis of distribution shift between demonstration data and the online environment; no mismatch, non-stationarity, or sim-to-real gap is quantified.
minor comments (2)
- [Method] Notation for the supervised pre-training loss and the offline/online RL objectives should be introduced with explicit equations rather than prose descriptions.
- [Abstract] The abstract's reference to 'low-quality demonstration data' should be accompanied by a precise definition (e.g., noise level or sub-optimality measure) in the experimental section.
Simulated Author's Rebuttal
We thank the referee for the constructive feedback on the clarity of our experimental claims and the analysis of the fine-tuning process. We address each major comment below.
read point-by-point responses
-
Referee: [Abstract, §Experiments] Abstract and §Experiments: the headline claim that SRL implementations 'significantly outperform all benchmarks' is stated without any reported baselines, metrics (e.g., cost, regret, or constraint violation), statistical tests, or error bars; the reader cannot verify whether results support superiority or reflect post-hoc selection.
Authors: We agree that additional detail is needed to substantiate the superiority claims. While the manuscript reports cost-efficiency comparisons against benchmarks, we acknowledge the absence of explicit error bars, statistical tests, and a consolidated table of metrics. In the revision, we will add error bars to all relevant plots, include a summary table listing all baselines and metrics (cost, constraint violations where applicable), and report statistical significance tests to enable verification of the results. revision: yes
-
Referee: [Fine-tuning process description] § on two-step fine-tuning: the central assumption that offline-then-online fine-tuning reliably adapts the policy to real-world dynamics without instability or excessive sample cost is not supported by any reported analysis of distribution shift between demonstration data and the online environment; no mismatch, non-stationarity, or sim-to-real gap is quantified.
Authors: The empirical results demonstrate successful adaptation via the two-step process, including under low-quality demonstrations. However, the manuscript does not provide a dedicated quantitative analysis of distribution shift, non-stationarity, or sim-to-real gaps. We will revise the paper to add a discussion subsection (with supporting plots if available) that quantifies observed shifts between demonstration data and the online environment and addresses potential instability or sample costs. revision: yes
Circularity Check
No significant circularity in derivation chain
full rationale
The paper proposes an SRL framework consisting of supervised pre-training on demonstration data followed by a two-step (offline then online) RL fine-tuning process. No equations, fitted parameters, or mathematical derivations are presented in the provided text that would reduce any claimed prediction or result to an input by construction. The central claim of outperformance is supported by experimental results rather than a self-referential derivation or load-bearing self-citation chain. This is a standard empirical method paper with no visible instances of the enumerated circularity patterns.
Axiom & Free-Parameter Ledger
read the original abstract
The increasing integration of distributed energy resources (DERs) is crucial for power system decarbonization, yet unlocking DERs' flexibility is challenged by their inherent uncertainties and modelling complexity. As traditional optimization methods struggle with such uncertainty and complexity of DERs, reinforcement learning (RL) has emerged as a promising alternative for DER management. However, standard RL methods suffer from sample inefficiency and sub-optimality when trained from scratch. Inspired by the training paradigms in large language models, this paper proposes a Supervised Reinforcement Learning (SRL) framework for learning DER coordination policies. This framework first pre-trains a policy on demonstration data in a supervised-learning fashion, which is then further fine-tuned using RL. Furthermore, we propose a two-step fine-tuning process: offline fine-tuning for enhancing policy performance and online fine-tuning for adapting it to the real-world dynamics. Experiments demonstrate that RL implementations based on the proposed framework significantly outperform all benchmarks, achieving high cost efficiency even under low-quality demonstration data.
Figures
Reference graph
Works this paper leans on
-
[1]
Digitalisation and Energy,
The International Energy Agency (IEA), “Digitalisation and Energy,” www.iea.org/reports/digitalisation-and-energy, The International Energy Agency (IEA), Technical Report, Accessed: 2025-05-22
2025
-
[2]
Aggregated feasible active power region for distributed energy resources with a distributionally robust joint probabilistic guarantee,
Y . Zhou, C. Essayeh, and T. Morstyn, “Aggregated feasible active power region for distributed energy resources with a distributionally robust joint probabilistic guarantee,”IEEE Transactions on Power Systems, vol. 40, no. 1, pp. 556–571, 2024
2024
-
[3]
Incorporating charger efficiency into electric vehicle charging optimization,
C. Crozier, M. Deakin, T. Morstyn, and M. McCulloch, “Incorporating charger efficiency into electric vehicle charging optimization,” inISGT- Europe, 2019, pp. 1–5
2019
-
[4]
A control framework to enable a commercial building hvac system for energy and regulation market signal tracking,
W. Wang, G. Tian, Q. Z. Sun, and H. Liu, “A control framework to enable a commercial building hvac system for energy and regulation market signal tracking,”IEEE Transactions on Power Systems, vol. 38, no. 1, pp. 290–301, 2023
2023
-
[5]
Deep reinforcement learning for power system applications: An overview,
Z. Zhang, D. Zhang, and R. C. Qiu, “Deep reinforcement learning for power system applications: An overview,”CSEE Journal of Power and Energy Systems, vol. 6, no. 1, pp. 213–225, 2020
2020
-
[6]
Deep reinforcement learning control of electric vehicle charging in the presence of photovoltaic generation,
M. Dorokhova, Y . Martinson, C. Ballif, and N. Wyrsch, “Deep reinforcement learning control of electric vehicle charging in the presence of photovoltaic generation,”Applied Energy, vol. 301, p. 117504, 2021. [Online]. Available: https://www.sciencedirect.com/ science/article/pii/S0306261921008874
2021
-
[7]
An uncertainty-aware deep reinforcement learning framework for residential air conditioning energy management,
C. Lork, W.-T. Li, Y . Qin, Y . Zhou, C. Yuen, W. Tushar, and T. K. Saha, “An uncertainty-aware deep reinforcement learning framework for residential air conditioning energy management,” Applied Energy, vol. 276, p. 115426, 2020. [Online]. Available: https://www.sciencedirect.com/science/article/pii/S0306261920309387
2020
-
[8]
On-line building energy optimization using deep reinforcement learning,
E. Mocanu, D. C. Mocanu, P. H. Nguyen, A. Liotta, M. E. Webber, M. Gibescu, and J. G. Slootweg, “On-line building energy optimization using deep reinforcement learning,”IEEE Transactions on Smart Grid, vol. 10, no. 4, pp. 3698–3708, 2019
2019
-
[9]
Deep reinforcement learning for smart home energy management,
L. Yu, W. Xie, D. Xie, Y . Zou, D. Zhang, Z. Sun, L. Zhang, Y . Zhang, and T. Jiang, “Deep reinforcement learning for smart home energy management,”IEEE Internet of Things Journal, vol. 7, no. 4, pp. 2751– 2762, 2020
2020
-
[10]
Secure energy management of multi-energy microgrid: A physical-informed safe reinforcement learning approach,
Y . Wang, D. Qiu, M. Sun, G. Strbac, and Z. Gao, “Secure energy management of multi-energy microgrid: A physical-informed safe reinforcement learning approach,”Applied Energy, vol. 335, p. 120759, 2023. [Online]. Available: https://www.sciencedirect.com/ science/article/pii/S030626192300123X
2023
-
[11]
Forecasting error-aware optimal dispatch of wind-storage integrated power systems: A soft-actor-critic deep reinforcement learning approach,
Z. Li, Y . Xiang, and J. Liu, “Forecasting error-aware optimal dispatch of wind-storage integrated power systems: A soft-actor-critic deep reinforcement learning approach,”Energy, vol. 318, p. 134798, 2025. [Online]. Available: https://www.sciencedirect.com/science/article/pii/ S0360544225004402
2025
-
[12]
Understanding the Effects of RLHF on LLM Generalisation and Diversity
R. Kirk, I. Mediratta, C. Nalmpantis, J. Luketina, E. Hambro, E. Grefenstette, and R. Raileanu, “Understanding the effects of rlhf on llm generalisation and diversity,” 2024. [Online]. Available: https://arxiv.org/abs/2310.06452
work page internal anchor Pith review Pith/arXiv arXiv 2024
-
[13]
Training a Helpful and Harmless Assistant with Reinforcement Learning from Human Feedback
Y . Baiet al., “Training a helpful and harmless assistant with reinforcement learning from human feedback,” 2022. [Online]. Available: https://arxiv.org/abs/2204.05862 24th Power Systems Computation Conference PSCC 2026 Limassol, Cyprus — June 8-12, 2026
work page internal anchor Pith review Pith/arXiv arXiv 2022
-
[14]
Multiagent imitation learning-based energy management of a microgrid with hybrid energy storage and real-time pricing,
S. Gao, Y . Xu, Z. Zhang, Z. Wang, X. Zhou, and J. Wang, “Multiagent imitation learning-based energy management of a microgrid with hybrid energy storage and real-time pricing,”IEEE Internet of Things Journal, vol. 12, no. 12, pp. 19 801–19 817, 2025
2025
-
[15]
Online optimal power scheduling of a microgrid via imitation learning,
S. Gao, C. Xiang, M. Yu, K. T. Tan, and T. H. Lee, “Online optimal power scheduling of a microgrid via imitation learning,”IEEE Transac- tions on Smart Grid, vol. 13, no. 2, pp. 861–876, 2022
2022
-
[16]
Scalable multi- agent reinforcement learning for distributed control of residential energy flexibility,
F. Charbonnier, T. Morstyn, and M. D. McCulloch, “Scalable multi- agent reinforcement learning for distributed control of residential energy flexibility,”Applied Energy, vol. 314, p. 118825, 2022
2022
-
[17]
Real-time power scheduling through reinforcement learning from demonstrations,
S. Liu, J. Liu, N. Yang, Y . Huang, Q. Jiang, and Y . Gao, “Real-time power scheduling through reinforcement learning from demonstrations,”Electric Power Systems Research, vol. 235, p. 110638, 2024. [Online]. Available: https://www.sciencedirect.com/ science/article/pii/S0378779624005248
2024
-
[18]
Cal-ql: Calibrated offline rl pre-training for efficient online fine-tuning,
M. Nakamoto, S. Zhai, A. Singh, M. Sobol Mark, Y . Ma, C. Finn, A. Kumar, and S. Levine, “Cal-ql: Calibrated offline rl pre-training for efficient online fine-tuning,” inAdvances in Neural Information Processing Systems, A. Oh, T. Naumann, A. Globerson, K. Saenko, M. Hardt, and S. Levine, Eds., vol. 36. Curran Associates, Inc., 2023, pp. 62 244–62 269. [O...
2023
-
[19]
Online pre-training for offline-to-online reinforcement learning,
Y . Shin, J. Kim, W. Jung, S. Hong, D. Yoon, Y . Jang, G. Kim, J. Chae, Y . Sung, K. Lee, and W. Lim, “Online pre-training for offline-to-online reinforcement learning,” 2025. [Online]. Available: https://arxiv.org/abs/2507.08387
-
[20]
Model pre- dictive control for distributed microgrid battery energy storage systems,
T. Morstyn, B. Hredzak, R. P. Aguilera, and V . G. Agelidis, “Model pre- dictive control for distributed microgrid battery energy storage systems,” IEEE Transactions on Control Systems Technology, vol. 26, no. 3, pp. 1107–1114, 2018
2018
-
[21]
Aggregate flexibility of thermostatically controlled loads,
H. Hao, B. M. Sanandaji, K. Poolla, and T. L. Vincent, “Aggregate flexibility of thermostatically controlled loads,”IEEE Transactions on Power Systems, vol. 30, no. 1, pp. 189–198, 2015
2015
-
[22]
Proximal Policy Optimization Algorithms
J. Schulman, F. Wolski, P. Dhariwal, A. Radford, and O. Klimov, “Proximal policy optimization algorithms,” 2017. [Online]. Available: https://arxiv.org/abs/1707.06347
work page internal anchor Pith review Pith/arXiv arXiv 2017
-
[23]
The impact of future heat demand pathways on the economics of low carbon heating systems,
R. Sansom and G. Strbac, “The impact of future heat demand pathways on the economics of low carbon heating systems,” inBIEE-9th Academic conference, no. September, 2012, p. 10
2012
-
[24]
The modern-era retrospective analysis for research and applications, version 2 (merra-2),
R. Gelaroet al., “The modern-era retrospective analysis for research and applications, version 2 (merra-2),”Journal of Climate, vol. 30, no. 14, pp. 5419 – 5454, 2017. [Online]. Available: https: //journals.ametsoc.org/view/journals/clim/30/14/jcli-d-16-0758.1.xml
2017
-
[25]
Optimal scheduling for a multi-energy microgrid by a soft actor-critic deep reinforcement learning,
Y . Luo, C. Liu, and Q. Lai, “Optimal scheduling for a multi-energy microgrid by a soft actor-critic deep reinforcement learning,” in2022 IEEE Power & Energy Society General Meeting (PESGM), 2022, pp. 1–5
2022
-
[26]
Scenario reduction algorithms in stochastic programming,
H. Heitsch and W. R ¨omisch, “Scenario reduction algorithms in stochastic programming,”Computational optimization and applications, vol. 24, pp. 187–206, 2003. 24th Power Systems Computation Conference PSCC 2026 Limassol, Cyprus — June 8-12, 2026
2003
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.