Quantifying artificial intelligence through algorithmic generalization
November 08, 2024 Β· Declared Dead Β· π Nature Machine Intelligence
"No code URL or promise found in abstract"
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Authors
Takuya Ito, Murray Campbell, Lior Horesh, Tim Klinger, Parikshit Ram
arXiv ID
2411.05943
Category
cs.AI: Artificial Intelligence
Cross-listed
cs.CL,
cs.LG,
cs.LO
Citations
3
Venue
Nature Machine Intelligence
Last Checked
4 months ago
Abstract
The rapid development of artificial intelligence (AI) systems has created an urgent need for their scientific quantification. While their fluency across a variety of domains is impressive, AI systems fall short on tests requiring algorithmic reasoning -- a glaring limitation given the necessity for interpretable and reliable technology. Despite a surge of reasoning benchmarks emerging from the academic community, no theoretical framework exists to quantify algorithmic reasoning in AI systems. Here, we adopt a framework from computational complexity theory to quantify algorithmic generalization using algebraic expressions: algebraic circuit complexity. Algebraic circuit complexity theory -- the study of algebraic expressions as circuit models -- is a natural framework to study the complexity of algorithmic computation. Algebraic circuit complexity enables the study of generalization by defining benchmarks in terms of the computational requirements to solve a problem. Moreover, algebraic circuits are generic mathematical objects; an arbitrarily large number of samples can be generated for a specified circuit, making it an ideal experimental sandbox for the data-hungry models that are used today. In this Perspective, we adopt tools from algebraic circuit complexity, apply them to formalize a science of algorithmic generalization, and address key challenges for its successful application to AI science.
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