Adaptive Compute Efficient Learning via Conceptual-Criticality (Student Abstract)

Authors

  • Iñigo Parra UC Berkeley
  • Mano Bharathi M Opentext
  • Mayank Kumar Bennett University
  • Pushpa Kumar Balan University of Central Missouri
  • Priyadarsi Mishra Texas A&M University

DOI:

https://doi.org/10.1609/aaai.v40i48.42265

Abstract

The computational cost of large language models (LLMs) is a primary obstacle to sustainable deployment. Static resource allocation is inefficient, as not all inputs require the same depth of processing. We propose a framework for adaptive, compute-efficient learning via conceptual criticality, which dynamically tailors computation to the assessed difficulty of an input. A lightweight criticality prediction module es- timates conceptual complexity on a continuous scale, and this score governs the LLM’s inference pathway, selectively activating token pruning, layer skipping, and quantization. Simple inputs are processed with minimal FLOPs and la- tency, while complex inputs use the model’s full capacity to preserve accuracy. We benchmark our framework and in- troduce metrics to quantify sensitivity to input criticality and per-sample computational savings. Results demonstrate an improved accuracy-efficiency trade-off, paving the way for more resource-aware systems.

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Published

2026-03-14

How to Cite

Parra, I., M, M. B., Kumar, M., Balan, P. K., & Mishra, P. (2026). Adaptive Compute Efficient Learning via Conceptual-Criticality (Student Abstract). Proceedings of the AAAI Conference on Artificial Intelligence, 40(48), 41349–41351. https://doi.org/10.1609/aaai.v40i48.42265