toplogo
Iniciar sesión

Domain Adaptation for Offline Reinforcement Learning with Limited Samples: A Theoretical and Empirical Exploration


Conceptos Básicos
This paper proposes a novel framework for domain adaptation in offline reinforcement learning (RL) with limited target samples, theoretically analyzing the trade-off between leveraging a large, related source dataset and a limited target dataset, and providing empirical validation on the Procgen benchmark.
Resumen

Bibliographic Information:

Chen, W., Mishra, S., & Paternain, S. (2024). Domain Adaptation for Offline Reinforcement Learning with Limited Samples. arXiv preprint arXiv:2408.12136v2.

Research Objective:

This paper investigates the challenge of offline reinforcement learning with limited target data and explores how to effectively leverage a large, related source dataset through domain adaptation. The research aims to establish a theoretical framework for understanding the trade-off between source and target data utilization and validate the findings empirically.

Methodology:

The authors propose a framework that combines the target and source datasets with a weighting parameter (λ) to minimize the temporal difference (TD) error. They derive theoretical performance bounds, including expected and worst-case bounds, based on the number of target samples and the discrepancy (dynamics gap) between the source and target domains. The optimal weight (λ*) for minimizing the expected performance bound is derived. Empirical validation is performed using the offline Procgen Benchmark with the CQL algorithm, analyzing the impact of varying λ, the dynamics gap (ξ), and the number of target samples (N).

Key Findings:

  • The optimal weight for balancing source and target datasets is not trivial and depends on the dynamics gap and the number of target samples.
  • As the dynamics gap decreases, the optimal weight shifts towards prioritizing the source dataset.
  • Increasing the number of target samples leads to a higher reliance on the target dataset for optimal performance.
  • Empirical results on the Procgen benchmark support the theoretical findings, demonstrating the effectiveness of the proposed framework.

Main Conclusions:

The paper establishes a theoretical foundation for domain adaptation in offline RL with limited target data, providing insights into the trade-off between source and target data utilization. The derived performance bounds and the optimal weighting strategy offer practical guidance for leveraging related datasets in offline RL.

Significance:

This research contributes significantly to the field of offline RL by addressing the critical challenge of limited target data. The proposed framework and theoretical analysis provide valuable tools for improving the efficiency and practicality of offline RL in real-world applications where data collection is expensive or risky.

Limitations and Future Research:

The paper primarily focuses on minimizing the expected performance bound. Future research could explore tighter bounds and consider other performance metrics. Additionally, investigating the impact of different domain adaptation techniques within the proposed framework would be beneficial.

edit_icon

Personalizar resumen

edit_icon

Reescribir con IA

edit_icon

Generar citas

translate_icon

Traducir fuente

visual_icon

Generar mapa mental

visit_icon

Ver fuente

Estadísticas
The source dataset contains 40,000 samples. The target dataset contains 1,000 samples. The experiments use seven different weights (λ) for combining the source and target datasets: 0, 0.2, 0.4, 0.5, 0.6, 0.8, and 1.0. Three different source datasets are used, representing varying degrees of discrepancy (ξ) from the target domain. Three different target dataset sizes (N) are used: 1,000, 2,500, and 4,000 samples.
Citas
"To the best of our knowledge, this paper proposes the first framework that theoretically and experimentally explores how the weight assigned to each dataset affects the performance of offline RL." "Given the unlimited source dataset and the limited target dataset, however, striking the proper balance between the two datasets remains a challenging problem in offline RL." "Our empirical results on the well-known Procgen Benchmark substantiate our theoretical contributions."

Consultas más profundas

How can this framework be extended to incorporate multiple source datasets with varying degrees of relevance to the target domain?

This framework can be extended to incorporate multiple source datasets by modifying the objective function in equation (10) to include a weighted combination of TD errors from all datasets. Let's say we have $M$ source datasets, $D'_1, D'_2, ..., D'_M$, each with a corresponding weight $\lambda_1, \lambda_2, ..., \lambda_M$. The weights would reflect the relevance of each source dataset to the target domain, with higher weights assigned to more relevant datasets. The modified objective function would then become: $$Q_{k+1}^{\lambda_1,...,\lambda_M} = \arg\min_Q (1 - \sum_{i=1}^M \lambda_i) E_{\hat{D}}(Q) + \sum_{i=1}^M \lambda_i E_{D'_i}(Q)$$ Here's how to determine the weights: Domain Expertise: Leverage prior knowledge or expert opinions to assign initial weights based on the perceived similarity between each source dataset and the target domain. Discrepancy Measures: Utilize metrics like the maximum dynamics gap ($\xi$) calculated between each source dataset and the target dataset to quantify their dissimilarity. Assign higher weights to source datasets with lower discrepancy measures. Adversarial Training: Train a discriminator network to distinguish between samples from the target dataset and each source dataset. The discriminator's confidence in classifying samples can be used to estimate the relevance of each source dataset, informing the weight assignment. The theoretical analysis would need to be extended to account for the multiple source datasets. The performance bounds would then depend on the weights and the discrepancies between the target dataset and each source dataset.

Could the reliance on a pre-defined weighting parameter ($\lambda$) be replaced with a more adaptive mechanism that dynamically adjusts the balance between source and target data during training?

Yes, the reliance on a pre-defined weighting parameter ($\lambda$) can be replaced with a more adaptive mechanism that dynamically adjusts the balance between source and target data during training. Here are a few approaches: Uncertainty-Based Weighting: Estimate the uncertainty of the Q-function on both the source and target data. This could be done using techniques like dropout or ensemble methods. Assign higher weights to the dataset where the Q-function has higher uncertainty. This encourages the model to focus on areas where it can learn the most from either domain. Adversarial Domain Adaptation: Train a discriminator network to distinguish between features from the source and target domains. Minimize the discriminator's ability to distinguish between the domains while simultaneously training the RL agent to maximize its performance on the weighted combination of source and target data. The weights can be dynamically adjusted based on the discriminator's performance, with higher weights assigned to the source domain when the discriminator performs well (indicating a need for more domain adaptation). Meta-Learning: Treat the weight parameter ($\lambda$) as a meta-parameter and learn it alongside the Q-function parameters. This can be done using meta-learning algorithms that optimize for performance on a validation set from the target domain. This allows the model to automatically discover the optimal balance between source and target data throughout the training process. These adaptive mechanisms can potentially lead to better performance than using a fixed weight, as they allow the model to dynamically adjust the balance between source and target data based on its learning progress and the characteristics of the data.

What are the ethical implications of using domain adaptation in offline RL, particularly in safety-critical applications where biased source data could lead to undesirable outcomes?

Using domain adaptation in offline RL, especially in safety-critical applications, presents significant ethical implications, primarily due to the potential for biased source data to propagate and amplify existing biases, leading to unfair or even harmful outcomes. Here's a breakdown of the key concerns: Amplification of Existing Biases: Source datasets, often collected from real-world scenarios, can inherently contain biases reflecting societal prejudices or historical inequalities. Directly transferring knowledge from such biased datasets to the target domain without careful consideration can perpetuate and even exacerbate these biases. For instance, a healthcare system trained on a dataset skewed towards a particular demographic might lead to less effective treatment strategies for under-represented groups. Lack of Transparency and Accountability: The process of domain adaptation, especially when using complex techniques like adversarial training, can be opaque, making it challenging to understand how the source data influences the final policy. This lack of transparency can hinder accountability, making it difficult to identify and rectify biased or unfair outcomes. Exacerbation of Inequality: In safety-critical applications like autonomous driving or medical diagnosis, biased decision-making can have severe consequences, potentially leading to accidents or misdiagnoses. If the domain adaptation process is not carefully designed and validated, it could disproportionately impact vulnerable populations, further marginalizing already disadvantaged groups. To mitigate these ethical risks, it's crucial to: Critically Evaluate Source Data: Thoroughly analyze the source datasets for potential biases before using them for domain adaptation. Employ bias detection tools and techniques to identify and understand any existing biases. Develop Fair and Transparent Algorithms: Design domain adaptation algorithms that promote fairness and transparency. Explore techniques like fairness constraints or adversarial debiasing to mitigate bias propagation. Rigorous Testing and Validation: Conduct extensive testing and validation of the trained RL agent in realistic scenarios, paying close attention to potential disparities in performance across different demographic groups. Establish Clear Accountability Mechanisms: Define clear lines of responsibility for the decisions made by the RL agent. Implement mechanisms for auditing and redressing any unfair or biased outcomes. Addressing these ethical considerations is paramount to ensure that domain adaptation in offline RL, particularly in safety-critical applications, leads to equitable and just outcomes for all stakeholders.
0
star