Performance is not All You Need: Sustainability Considerations for Algorithms

• URL: http://arxiv.org/abs/2509.00045v2
• Date: Wed, 03 Sep 2025 05:15:22 GMT
• Title: Performance is not All You Need: Sustainability Considerations for Algorithms
• Authors: Xiang Li, Chong Zhang, Hongpeng Wang, Shreyank Narayana Gowda, Yushi Li, Xiaobo Jin,
• Abstract summary: This work focuses on the high carbon emissions generated by deep learning model training.<n>It proposes an innovative two-dimensional sustainability evaluation system.<n>Our sustainability evaluation framework code can be found here, providing methodological support for the industry to establish algorithm energy efficiency standards.
• Score: 19.440317792116833
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: This work focuses on the high carbon emissions generated by deep learning model training, specifically addressing the core challenge of balancing algorithm performance and energy consumption. It proposes an innovative two-dimensional sustainability evaluation system. Different from the traditional single performance-oriented evaluation paradigm, this study pioneered two quantitative indicators that integrate energy efficiency ratio and accuracy: the sustainable harmonic mean (FMS) integrates accumulated energy consumption and performance parameters through the harmonic mean to reveal the algorithm performance under unit energy consumption; the area under the sustainability curve (ASC) constructs a performance-power consumption curve to characterize the energy efficiency characteristics of the algorithm throughout the cycle. To verify the universality of the indicator system, the study constructed benchmarks in various multimodal tasks, including image classification, segmentation, pose estimation, and batch and online learning. Experiments demonstrate that the system can provide a quantitative basis for evaluating cross-task algorithms and promote the transition of green AI research from theory to practice. Our sustainability evaluation framework code can be found here, providing methodological support for the industry to establish algorithm energy efficiency standards.

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