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ALARM: Hierarchical Rewards Modeling for Language Model Alignment


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The author introduces ALARM, a framework that hierarchically models rewards in reinforcement learning from human feedback to enhance alignment of large language models with human preferences.
Resumo

ALARM is a novel framework that addresses the limitations of current alignment approaches by integrating holistic rewards with aspect-specific rewards. It provides more precise and consistent guidance for language models towards desired outcomes, particularly in complex text generation tasks. The framework has been validated through applications in question answering and machine translation tasks, showcasing improvements over existing baselines.

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Estatísticas
We introduce ALARM, the first framework modeling hierarchical rewards in reinforcement learning from human feedback (RLHF). The framework integrates holistic rewards with aspect-specific rewards to provide more precise and consistent guidance for language models. ALARM has been validated through applications in long-form question answering and machine translation tasks. The framework demonstrates improvements over existing baselines. ALARM underscores the effectiveness of hierarchical rewards modeling in refining LLM training processes for better human preference alignment.
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by Yuhang Lai,S... às arxiv.org 03-12-2024

https://arxiv.org/pdf/2403.06754.pdf
ALaRM

Perguntas Mais Profundas

How can the hierarchical structure of ALARM be applied to other areas beyond text generation tasks?

The hierarchical structure of ALARM, which models both holistic and aspect-specific rewards in reinforcement learning from human feedback (RLHF), can be applied to various other domains beyond text generation tasks. One potential application is in image recognition tasks, where different aspects such as clarity, color accuracy, and object detection could be considered as aspect-specific rewards. By hierarchically combining these rewards with a holistic reward for overall image quality, the model can be guided towards better alignment with human preferences. Another area where this hierarchical structure could prove beneficial is in healthcare applications. For instance, in medical diagnosis tasks, specific aspects like accuracy of diagnosis or patient outcome prediction could serve as aspect-specific rewards. These could be combined hierarchically with an overall assessment of the diagnostic process to improve the model's performance and alignment with medical professionals' preferences. Furthermore, in autonomous driving systems, aspects such as safety compliance, traffic rule adherence, and pedestrian detection accuracy could be considered for hierarchical reward modeling. By combining these specific aspects with an overarching measure of driving performance aligned with human expectations, AI systems can be trained more effectively for safe and reliable autonomous operation.

How might the concept of scalable oversight impact the future development of AI systems aligned with human preferences?

Scalable oversight plays a crucial role in ensuring that AI systems are developed and trained responsibly while aligning them with human preferences effectively. By incorporating scalable oversight mechanisms into AI development processes: Efficient Resource Utilization: Scalable oversight allows for effective utilization of limited human resources by focusing on key areas that require supervision or intervention. This ensures that valuable feedback is provided where it matters most without overwhelming humans with unnecessary tasks. Improved Model Performance: With scalable oversight mechanisms in place, AI systems can receive consistent and high-quality supervision signals within resource constraints. This leads to improved model performance through more accurate guidance based on diverse perspectives and feedback sources. Ethical Considerations: Scalable oversight helps address ethical considerations by ensuring that AI systems adhere to regulatory guidelines and societal norms while aligning closely with user preferences. It enables continuous monitoring and adjustment based on evolving ethical standards. Adaptability: The concept of scalable oversight allows AI systems to adapt to changing environments or user requirements efficiently by providing flexible mechanisms for gathering feedback at scale. This adaptability enhances the system's ability to stay relevant over time. 5Trustworthiness: Implementing scalable oversight instills trust among users regarding how their data is used and how decisions are made by AI systems aligned with their preferences.

What potential challenges or criticisms could arise from relying on human feedback for reinforcement learning?

While relying on human feedback for reinforcement learning offers several benefits such as interpretability and alignment with real-world objectives, there are also potential challenges and criticisms associated: 1Subjectivity: Human judgments may vary due to individual biases, preferences,and interpretations leadingto subjective labels that may not always reflect ground truth. 2Inconsistency: Humans may provide inconsistentfeedback across different instancesor contexts,resultingin noisyand unreliable supervision signalsthat hinderthe trainingprocess. 3Scalability: Collectinghumanfeedbackat scalecanbe costly,time-consuming,and labor-intensive,makingit challengingto apply RLHFapproachesto large-scaleapplications. 4Annotation Quality: The qualityofhumanannotations,suchaslabelaccuracyand granularity,mayvaryaffectingthe effectivenessof thereinforcementlearningprocess. 5Bias: Humanfeedbackmay inadvertentlyintroducebiasinto themodeltrainingprocessbasedon annotatorcharacteristicsor societalprejudicesleadingto unfairoutcomesorcognitivebiasesin themodelsdevelopedfromsuchdata 6**Privacy Concerns: Relying heavilyonhumanfeedbackforreinforcementlearningmayraisepotentialprivacyconcernssurroundingsensitiveinformationsharedbyannotatorsduringthelabelingevaluationprocess Itisimportanttobe awareofthesecriticismsandchallengesto mitigatetheirimpactthroughcarefuldesignoffeedbackcollectionstrategies,datacleanse,andevaluationmethodswhileleveragingthebenefitsofhumansupervisionforimprovingAImodelsalignedwithuserpreferences
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