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Main Authors: Whitfill, Parker, Snodin, Ben, Becker, Joel
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.19492
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author Whitfill, Parker
Snodin, Ben
Becker, Joel
author_facet Whitfill, Parker
Snodin, Ben
Becker, Joel
contents METR's time horizon metric has grown exponentially since 2019, along with compute. However, it is unclear whether compute scaling will persist at current rates through 2030, raising the question of how possible compute slowdowns might impact AI agent capability forecasts. Given a model of time horizon as a function of training compute and algorithms, along with a model of how compute investment spills into algorithmic progress (which, notably, precludes the possibility of a software-only singularity), and the empirical fact that both time horizon and compute have grown at constant rates over 2019--2025, we derive that time horizon growth must be proportional to compute growth. We provide additional, albeit limited, experimental evidence consistent with this theory. We use our model to project time horizon growth under OpenAI's compute projection, finding substantial projected delays in some cases. For example, 1-month time horizons at $80\%$ reliability occur $7$ years later than simple trend extrapolation suggests.
format Preprint
id arxiv_https___arxiv_org_abs_2511_19492
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Forecasting AI Time Horizon Under Compute Slowdowns
Whitfill, Parker
Snodin, Ben
Becker, Joel
Computers and Society
Artificial Intelligence
METR's time horizon metric has grown exponentially since 2019, along with compute. However, it is unclear whether compute scaling will persist at current rates through 2030, raising the question of how possible compute slowdowns might impact AI agent capability forecasts. Given a model of time horizon as a function of training compute and algorithms, along with a model of how compute investment spills into algorithmic progress (which, notably, precludes the possibility of a software-only singularity), and the empirical fact that both time horizon and compute have grown at constant rates over 2019--2025, we derive that time horizon growth must be proportional to compute growth. We provide additional, albeit limited, experimental evidence consistent with this theory. We use our model to project time horizon growth under OpenAI's compute projection, finding substantial projected delays in some cases. For example, 1-month time horizons at $80\%$ reliability occur $7$ years later than simple trend extrapolation suggests.
title Forecasting AI Time Horizon Under Compute Slowdowns
topic Computers and Society
Artificial Intelligence
url https://arxiv.org/abs/2511.19492