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Main Authors: Ray, Kaustabha, Gonzalez, Nelson Mimura, Wassermann, Bruno, Tzoref-Brill, Rachel, Lorenz, Dean H.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.09319
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author Ray, Kaustabha
Gonzalez, Nelson Mimura
Wassermann, Bruno
Tzoref-Brill, Rachel
Lorenz, Dean H.
author_facet Ray, Kaustabha
Gonzalez, Nelson Mimura
Wassermann, Bruno
Tzoref-Brill, Rachel
Lorenz, Dean H.
contents Large Language Model (LLM) inference systems present significant challenges in statistical performance characterization due to dynamic workload variations, diverse hardware architectures, and complex interactions between model size, batch processing, and throughput requirements. Accurate statistical characterization enables better workload scheduling, adaptive resource provisioning, and cost-aware inference optimization, making it crucial for improving efficiency in large-scale AI deployments. Traditional analytical models provide explainability but cannot cover the vast diversity of real-world workloads, making it impossible to benchmark every scenario in advance. Machine learning (ML) approaches effectively predict performance for non-benchmarked cases but struggle when extrapolating beyond their observed training space. To address these limitations for LLM inference systems, we propose an Analytical with Learning Augmentation (ALA) framework that bridges analytical modeling with \ml for robust statistical prediction and uncertainty estimation in LLM inference workloads. Our method employs an analytical throughput model with parameters estimated for benchmarked workloads, then extends to unobserved configurations using \ml predictions. We enhance this with simulated annealing to exploit subsets of the workload data point combinations and develop an error predictor. Finally, we quantify uncertainty based on vector space similarity between new and observed workloads to ensure robust generalization. Through extensive experimentation on diverse LLM inference workloads, we demonstrate that our framework achieves low median errors while maintaining adaptability to new inference scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2505_09319
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Statistical Modeling and Uncertainty Estimation of LLM Inference Systems
Ray, Kaustabha
Gonzalez, Nelson Mimura
Wassermann, Bruno
Tzoref-Brill, Rachel
Lorenz, Dean H.
Performance
Large Language Model (LLM) inference systems present significant challenges in statistical performance characterization due to dynamic workload variations, diverse hardware architectures, and complex interactions between model size, batch processing, and throughput requirements. Accurate statistical characterization enables better workload scheduling, adaptive resource provisioning, and cost-aware inference optimization, making it crucial for improving efficiency in large-scale AI deployments. Traditional analytical models provide explainability but cannot cover the vast diversity of real-world workloads, making it impossible to benchmark every scenario in advance. Machine learning (ML) approaches effectively predict performance for non-benchmarked cases but struggle when extrapolating beyond their observed training space. To address these limitations for LLM inference systems, we propose an Analytical with Learning Augmentation (ALA) framework that bridges analytical modeling with \ml for robust statistical prediction and uncertainty estimation in LLM inference workloads. Our method employs an analytical throughput model with parameters estimated for benchmarked workloads, then extends to unobserved configurations using \ml predictions. We enhance this with simulated annealing to exploit subsets of the workload data point combinations and develop an error predictor. Finally, we quantify uncertainty based on vector space similarity between new and observed workloads to ensure robust generalization. Through extensive experimentation on diverse LLM inference workloads, we demonstrate that our framework achieves low median errors while maintaining adaptability to new inference scenarios.
title Statistical Modeling and Uncertainty Estimation of LLM Inference Systems
topic Performance
url https://arxiv.org/abs/2505.09319